what is the importance of research for you

What Is the Importance of Research? 5 Reasons Why Research is Critical

by Logan Bessant | Nov 16, 2021 | Science

Most of us appreciate that research is a crucial part of medical advancement. But what exactly is the importance of research? In short, it is critical in the development of new medicines as well as ensuring that existing treatments are used to their full potential.

Research can bridge knowledge gaps and change the way healthcare practitioners work by providing solutions to previously unknown questions.

In this post, we’ll discuss the importance of research and its impact on medical breakthroughs.

The Importance Of Health Research

The purpose of studying is to gather information and evidence, inform actions, and contribute to the overall knowledge of a certain field. None of this is possible without research.

Understanding how to conduct research and the importance of it may seem like a very simple idea to some, but in reality, it’s more than conducting a quick browser search and reading a few chapters in a textbook.

No matter what career field you are in, there is always more to learn. Even for people who hold a Doctor of Philosophy (PhD) in their field of study, there is always some sort of unknown that can be researched. Delving into this unlocks the unknowns, letting you explore the world from different perspectives and fueling a deeper understanding of how the universe works.

To make things a little more specific, this concept can be clearly applied in any healthcare scenario. Health research has an incredibly high value to society as it provides important information about disease trends and risk factors, outcomes of treatments, patterns of care, and health care costs and use. All of these factors as well as many more are usually researched through a clinical trial.

What Is The Importance Of Clinical Research?

Clinical trials are a type of research that provides information about a new test or treatment. They are usually carried out to find out what, or if, there are any effects of these procedures or drugs on the human body.

All legitimate clinical trials are carefully designed, reviewed and completed, and need to be approved by professionals before they can begin. They also play a vital part in the advancement of medical research including:

Providing new and good information on which types of drugs are more effective.
Bringing new treatments such as medicines, vaccines and devices into the field.
Testing the safety and efficacy of a new drug before it is brought to market and used in clinical practice.
Giving the opportunity for more effective treatments to benefit millions of lives both now and in the future.
Enhancing health, lengthening life, and reducing the burdens of illness and disability.

This all plays back to clinical research as it opens doors to advancing prevention, as well as providing treatments and cures for diseases and disabilities. Clinical trial volunteer participants are essential to this progress which further supports the need for the importance of research to be well-known amongst healthcare professionals, students and the general public.

The image shows a researchers hand holding a magnifying glass to signify the importance of research.

Five Reasons Why Research is Critical

Research is vital for almost everyone irrespective of their career field. From doctors to lawyers to students to scientists, research is the key to better work.

Increases quality of life

Research is the backbone of any major scientific or medical breakthrough. None of the advanced treatments or life-saving discoveries used to treat patients today would be available if it wasn’t for the detailed and intricate work carried out by scientists, doctors and healthcare professionals over the past decade.

This improves quality of life because it can help us find out important facts connected to the researched subject. For example, universities across the globe are now studying a wide variety of things from how technology can help breed healthier livestock, to how dance can provide long-term benefits to people living with Parkinson’s.

For both of these studies, quality of life is improved. Farmers can use technology to breed healthier livestock which in turn provides them with a better turnover, and people who suffer from Parkinson’s disease can find a way to reduce their symptoms and ease their stress.

Research is a catalyst for solving the world’s most pressing issues. Even though the complexity of these issues evolves over time, they always provide a glimmer of hope to improving lives and making processes simpler.

Builds up credibility

People are willing to listen and trust someone with new information on one condition – it’s backed up. And that’s exactly where research comes in. Conducting studies on new and unfamiliar subjects, and achieving the desired or expected outcome, can help people accept the unknown.

However, this goes without saying that your research should be focused on the best sources. It is easy for people to poke holes in your findings if your studies have not been carried out correctly, or there is no reliable data to back them up.

This way once you have done completed your research, you can speak with confidence about your findings within your field of study.

Drives progress forward

It is with thanks to scientific research that many diseases once thought incurable, now have treatments. For example, before the 1930s, anyone who contracted a bacterial infection had a high probability of death. There simply was no treatment for even the mildest of infections as, at the time, it was thought that nothing could kill bacteria in the gut.

When antibiotics were discovered and researched in 1928, it was considered one of the biggest breakthroughs in the medical field. This goes to show how much research drives progress forward, and how it is also responsible for the evolution of technology .

Today vaccines, diagnoses and treatments can all be simplified with the progression of medical research, making us question just what research can achieve in the future.

Engages curiosity

The acts of searching for information and thinking critically serve as food for the brain, allowing our inherent creativity and logic to remain active. Aside from the fact that this curiosity plays such a huge part within research, it is also proven that exercising our minds can reduce anxiety and our chances of developing mental illnesses in the future.

Without our natural thirst and our constant need to ask ‘why?’ and ‘how?’ many important theories would not have been put forward and life-changing discoveries would not have been made. The best part is that the research process itself rewards this curiosity.

Research opens you up to different opinions and new ideas which can take a proposed question and turn into a real-life concept. It also builds discerning and analytical skills which are always beneficial in many career fields – not just scientific ones.

Increases awareness

The main goal of any research study is to increase awareness, whether it’s contemplating new concepts with peers from work or attracting the attention of the general public surrounding a certain issue.

Around the globe, research is used to help raise awareness of issues like climate change, racial discrimination, and gender inequality. Without consistent and reliable studies to back up these issues, it would be hard to convenience people that there is a problem that needs to be solved in the first place.

The problem is that social media has become a place where fake news spreads like a wildfire, and with so many incorrect facts out there it can be hard to know who to trust. Assessing the integrity of the news source and checking for similar news on legitimate media outlets can help prove right from wrong.

This can pinpoint fake research articles and raises awareness of just how important fact-checking can be.

The Importance Of Research To Students

It is not a hidden fact that research can be mentally draining, which is why most students avoid it like the plague. But the matter of fact is that no matter which career path you choose to go down, research will inevitably be a part of it.

But why is research so important to students ? The truth is without research, any intellectual growth is pretty much impossible. It acts as a knowledge-building tool that can guide you up to the different levels of learning. Even if you are an expert in your field, there is always more to uncover, or if you are studying an entirely new topic, research can help you build a unique perspective about it.

For example, if you are looking into a topic for the first time, it might be confusing knowing where to begin. Most of the time you have an overwhelming amount of information to sort through whether that be reading through scientific journals online or getting through a pile of textbooks. Research helps to narrow down to the most important points you need so you are able to find what you need to succeed quickly and easily.

It can also open up great doors in the working world. Employers, especially those in the scientific and medical fields, are always looking for skilled people to hire. Undertaking research and completing studies within your academic phase can show just how multi-skilled you are and give you the resources to tackle any tasks given to you in the workplace.

The Importance Of Research Methodology

There are many different types of research that can be done, each one with its unique methodology and features that have been designed to use in specific settings.

When showing your research to others, they will want to be guaranteed that your proposed inquiry needs asking, and that your methodology is equipt to answer your inquiry and will convey the results you’re looking for.

That’s why it’s so important to choose the right methodology for your study. Knowing what the different types of research are and what each of them focuses on can allow you to plan your project to better utilise the most appropriate methodologies and techniques available. Here are some of the most common types:

Theoretical Research: This attempts to answer a question based on the unknown. This could include studying phenomena or ideas whose conclusions may not have any immediate real-world application. Commonly used in physics and astronomy applications.
Applied Research: Mainly for development purposes, this seeks to solve a practical problem that draws on theory to generate practical scientific knowledge. Commonly used in STEM and medical fields.
Exploratory Research: Used to investigate a problem that is not clearly defined, this type of research can be used to establish cause-and-effect relationships. It can be applied in a wide range of fields from business to literature.
Correlational Research: This identifies the relationship between two or more variables to see if and how they interact with each other. Very commonly used in psychological and statistical applications.

The Importance Of Qualitative Research

This type of research is most commonly used in scientific and social applications. It collects, compares and interprets information to specifically address the “how” and “why” research questions.

Qualitative research allows you to ask questions that cannot be easily put into numbers to understand human experience because you’re not limited by survey instruments with a fixed set of possible responses.

Information can be gathered in numerous ways including interviews, focus groups and ethnographic research which is then all reported in the language of the informant instead of statistical analyses.

This type of research is important because they do not usually require a hypothesis to be carried out. Instead, it is an open-ended research approach that can be adapted and changed while the study is ongoing. This enhances the quality of the data and insights generated and creates a much more unique set of data to analyse.

The Process Of Scientific Research

No matter the type of research completed, it will be shared and read by others. Whether this is with colleagues at work, peers at university, or whilst it’s being reviewed and repeated during secondary analysis.

A reliable procedure is necessary in order to obtain the best information which is why it’s important to have a plan. Here are the six basic steps that apply in any research process.

Observation and asking questions: Seeing a phenomenon and asking yourself ‘How, What, When, Who, Which, Why, or Where?’. It is best that these questions are measurable and answerable through experimentation.
Gathering information: Doing some background research to learn what is already known about the topic, and what you need to find out.
Forming a hypothesis: Constructing a tentative statement to study.
Testing the hypothesis: Conducting an experiment to test the accuracy of your statement. This is a way to gather data about your predictions and should be easy to repeat.
Making conclusions: Analysing the data from the experiment(s) and drawing conclusions about whether they support or contradict your hypothesis.
Reporting: Presenting your findings in a clear way to communicate with others. This could include making a video, writing a report or giving a presentation to illustrate your findings.

Although most scientists and researchers use this method, it may be tweaked between one study and another. Skipping or repeating steps is common within, however the core principles of the research process still apply.

By clearly explaining the steps and procedures used throughout the study, other researchers can then replicate the results. This is especially beneficial for peer reviews that try to replicate the results to ensure that the study is sound.

What Is The Importance Of Research In Everyday Life?

Conducting a research study and comparing it to how important it is in everyday life are two very different things.

Carrying out research allows you to gain a deeper understanding of science and medicine by developing research questions and letting your curiosity blossom. You can experience what it is like to work in a lab and learn about the whole reasoning behind the scientific process. But how does that impact everyday life?

Simply put, it allows us to disprove lies and support truths. This can help society to develop a confident attitude and not believe everything as easily, especially with the rise of fake news.

Research is the best and reliable way to understand and act on the complexities of various issues that we as humans are facing. From technology to healthcare to defence to climate change, carrying out studies is the only safe and reliable way to face our future.

Not only does research sharpen our brains, but also helps us to understand various issues of life in a much larger manner, always leaving us questioning everything and fuelling our need for answers.

what is the importance of research for you

Logan Bessant is a dedicated science educator and the founder of Science Resource Online, launched in 2020. With a background in science education and a passion for accessible learning, Logan has built a platform that offers free, high-quality educational resources to learners of all ages and backgrounds.

What is STEM education?
How Stem Education Improves Student Learning
What Are the Three Domains for the Roles of Technology for Teaching and Learning?
Why Is FIDO2 Secure?

Featured Articles

The Significance of Workplace Incident Reporting Software

2.1 Why is Research Important

Learning objectives.

By the end of this section, you will be able to:

Explain how scientific research addresses questions about behavior
Discuss how scientific research guides public policy
Appreciate how scientific research can be important in making personal decisions

Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people’s authority, and blind luck. While many of us feel confident in our abilities to decipher and interact with the world around us, history is filled with examples of how very wrong we can be when we fail to recognize the need for evidence in supporting claims. At various times in history, we would have been certain that the sun revolved around a flat earth, that the earth’s continents did not move, and that mental illness was caused by possession (figure below). It is through systematic scientific research that we divest ourselves of our preconceived notions and superstitions and gain an objective understanding of ourselves and our world.

A skull has a large hole bored through the forehead.

Some of our ancestors, across the work and over the centuries, believed that trephination – the practice of making a hole in the skull, as shown here – allowed evil spirits to leave the body, thus curing mental illness and other diseases (credit” “taiproject/Flickr)

The goal of all scientists is to better understand the world around them. Psychologists focus their attention on understanding behavior, as well as the cognitive (mental) and physiological (body) processes that underlie behavior. In contrast to other methods that people use to understand the behavior of others, such as intuition and personal experience, the hallmark of scientific research is that there is evidence to support a claim. Scientific knowledge is empirical : It is grounded in objective, tangible evidence that can be observed time and time again, regardless of who is observing.

We can easily observe the behavior of others around us. For example, if someone is crying, we can observe that behavior. However, the reason for the behavior is more difficult to determine. Is the person crying due to being sad, in pain, or happy? Sometimes, asking about the underlying cognitions is as easy as asking the subject directly: “Why are you crying?” However, there are situations in which an individual is either uncomfortable or unwilling to answer the question honestly, or is incapable of answering. For example, infants would not be able to explain why they are crying. In other situations, it may be hard to identify exactly why you feel the way you do. Think about times when you suddenly feel annoyed after a long day. There may be a specific trigger for your annoyance (a loud noise), or you may be tired, hungry, stressed, or all of the above. Human behavior is often a complicated mix of a variety of factors. In such circumstances, the psychologist must be creative in finding ways to better understand behavior. This chapter explores how scientific knowledge is generated, and how important that knowledge is in forming decisions in our personal lives and in the public domain.

USE OF RESEARCH INFORMATION

In the meantime, we should strive to think critically about the information we encounter by exercising a degree of healthy skepticism. When someone makes a claim, we should examine the claim from a number of different perspectives: what is the expertise of the person making the claim, what might they gain if the claim is valid, does the claim seem justified given the evidence, and what do other researchers think of the claim? Science is always changing and new evidence is alwaus coming to light, thus this dash of skepticism should be applied to all research you interact with from now on. Yes, that includes the research presented in this textbook.

Evaluation of research findings can have widespread impact. Imagine that you have been elected as the governor of your state. One of your responsibilities is to manage the state budget and determine how to best spend your constituents’ tax dollars. As the new governor, you need to decide whether to continue funding the D.A.R.E. (Drug Abuse Resistance Education) program in public schools (figure below). This program typically involves police officers coming into the classroom to educate students about the dangers of becoming involved with alcohol and other drugs. According to the D.A.R.E. website (www.dare.org), this program has been very popular since its inception in 1983, and it is currently operating in 75% of school districts in the United States and in more than 40 countries worldwide. Sounds like an easy decision, right? However, on closer review, you discover that the vast majority of research into this program consistently suggests that participation has little, if any, effect on whether or not someone uses alcohol or other drugs (Clayton, Cattarello, & Johnstone, 1996; Ennett, Tobler, Ringwalt, & Flewelling, 1994; Lynam et al., 1999; Ringwalt, Ennett, & Holt, 1991). If you are committed to being a good steward of taxpayer money, will you fund this particular program, or will you try to find other programs that research has consistently demonstrated to be effective?

A D.A.R.E. poster reads “D.A.R.E. to resist drugs and violence.”

The D.A.R.E. program continues to be popular in schools around the world despite research suggesting that it is ineffective.

It is not just politicians who can benefit from using research in guiding their decisions. We all might look to research from time to time when making decisions in our lives. Imagine you just found out that a close friend has breast cancer or that one of your young relatives has recently been diagnosed with autism. In either case, you want to know which treatment options are most successful with the fewest side effects. How would you find that out? You would probably talk with a doctor or psychologist and personally review the research that has been done on various treatment options—always with a critical eye to ensure that you are as informed as possible.

In the end, research is what makes the difference between facts and opinions. Facts are observable realities, and opinions are personal judgments, conclusions, or attitudes that may or may not be accurate. In the scientific community, facts can be established only using evidence collected through empirical research.

THE PROCESS OF SCIENTIFIC RESEARCH

Two types of reasoning are used to make decisions within this model: Deductive and inductive. In deductive reasoning, ideas are tested against the empirical world. Think about a detective looking for clues and evidence to test their “hunch” about whodunit. In contrast, in inductive reasoning, empirical observations lead to new ideas. In other words, inductive reasoning involves gathering facts to create or refine a theory, rather than testing the theory by gathering facts (figure below). These processes are inseparable, like inhaling and exhaling, but different research approaches place different emphasis on the deductive and inductive aspects.

A diagram has a box at the top labeled “hypothesis or general premise” and a box at the bottom labeled “empirical observations.” On the left, an arrow labeled “inductive reasoning” goes from the bottom to top box. On the right, an arrow labeled “deductive reasoning” goes from the top to the bottom box.

Psychological research relies on both inductive and deductive reasoning.

In the scientific context, deductive reasoning begins with a generalization—one hypothesis—that is then used to reach logical conclusions about the real world. If the hypothesis is correct, then the logical conclusions reached through deductive reasoning should also be correct. A deductive reasoning argument might go something like this: All living things require energy to survive (this would be your hypothesis). Ducks are living things. Therefore, ducks require energy to survive (logical conclusion). In this example, the hypothesis is correct; therefore, the conclusion is correct as well. Sometimes, however, an incorrect hypothesis may lead to a logical but incorrect conclusion. Consider the famous example from Greek philosophy. A philosopher decided that human beings were “featherless bipeds”. Using deductive reasoning, all two-legged creatures without feathers must be human, right? Diogenes the Cynic (named because he was, well, a cynic) burst into the room with a freshly plucked chicken from the market and held it up exclaiming “Behold! I have brought you a man!”

Deductive reasoning starts with a generalization that is tested against real-world observations; however, inductive reasoning moves in the opposite direction. Inductive reasoning uses empirical observations to construct broad generalizations. Unlike deductive reasoning, conclusions drawn from inductive reasoning may or may not be correct, regardless of the observations on which they are based. For example, you might be a biologist attempting to classify animals into groups. You notice that quite a large portion of animals are furry and produce milk for their young (cats, dogs, squirrels, horses, hippos, etc). Therefore, you might conclude that all mammals (the name you have chosen for this grouping) have hair and produce milk. This seems like a pretty great hypothesis that you could test with deductive reasoning. You go out an look at a whole bunch of things and stumble on an exception: The coconut. Coconuts have hair and produce milk, but they don’t “fit” your idea of what a mammal is. So, using inductive reasoning given the new evidence, you adjust your theory again for an other round of data collection. Inductive and deductive reasoning work in tandem to help build and improve scientific theories over time.

We’ve stated that theories and hypotheses are ideas, but what sort of ideas are they, exactly? A theory is a well-developed set of ideas that propose an explanation for observed phenomena. Theories are repeatedly checked against the world, but they tend to be too complex to be tested all at once. Instead, researchers create hypotheses to test specific aspects of a theory.

A hypothesis is a testable prediction about how the world will behave if our theory is correct, and it is often worded as an if-then statement (e.g., if I study all night, I will get a passing grade on the test). The hypothesis is extremely important because it bridges the gap between the realm of ideas and the real world. As specific hypotheses are tested, theories are modified and refined to reflect and incorporate the result of these tests (figure below).

A diagram has four boxes: the top is labeled “theory,” the right is labeled “hypothesis,” the bottom is labeled “research,” and the left is labeled “observation.” Arrows flow in the direction from top to right to bottom to left and back to the top, clockwise. The top right arrow is labeled “use the hypothesis to form a theory,” the bottom right arrow is labeled “design a study to test the hypothesis,” the bottom left arrow is labeled “perform the research,” and the top left arrow is labeled “create or modify the theory.”

The scientific method of research includes proposing hypotheses, conducting research, and creating or modifying theories based on results.

To see how this process works, let’s consider a specific theory and a hypothesis that might be generated from that theory. As you’ll learn in a later chapter, the James-Lange theory of emotion asserts that emotional experience relies on the physiological arousal associated with the emotional state. If you walked out of your home and discovered a very aggressive snake waiting on your doorstep, your heart would begin to race and your stomach churn. According to the James-Lange theory, these physiological changes would result in your feeling of fear. A hypothesis that could be derived from this theory might be that a person who is unaware of the physiological arousal that the sight of the snake elicits will not feel fear.

A scientific hypothesis is also falsifiable, or capable of being shown to be incorrect. Recall from the introductory chapter that Sigmund Freud had lots of interesting ideas to explain various human behaviors (figure below). However, a major criticism of Freud’s theories is that many of his ideas are not falsifiable. The essential characteristic of Freud’s building blocks of personality, the id, ego, and superego, is that they are unconscious, and therefore people can’t observe them. Because they cannot be observed or tested in any way, it is impossible to say that they don’t exist, so they cannot be considered scientific theories. Despite this, Freud’s theories are widely taught in introductory psychology texts because of their historical significance for personality psychology and psychotherapy, and these remain the root of all modern forms of therapy.

(a)A photograph shows Freud holding a cigar. (b) The mind’s conscious and unconscious states are illustrated as an iceberg floating in water. Beneath the water’s surface in the “unconscious” area are the id, ego, and superego. The area just below the water’s surface is labeled “preconscious.” The area above the water’s surface is labeled “conscious.”

Many of the specifics of (a) Freud’s theories, such ad (b) his division on the mind into the id, ego, and superego, have fallen out of favor in recent decades because they are not falsifiable (i.e., cannot be verified through scientific investigation). In broader strokes, his views set the stage for much psychological thinking today, such as the idea that some psychological process occur at the level of the unconscious.

In contrast, the James-Lange theory does generate falsifiable hypotheses, such as the one described above. Some individuals who suffer significant injuries to their spinal columns are unable to feel the bodily changes that often accompany emotional experiences. Therefore, we could test the hypothesis by determining how emotional experiences differ between individuals who have the ability to detect these changes in their physiological arousal and those who do not. In fact, this research has been conducted and while the emotional experiences of people deprived of an awareness of their physiological arousal may be less intense, they still experience emotion (Chwalisz, Diener, & Gallagher, 1988).

Scientific research’s dependence on falsifiability allows for great confidence in the information that it produces. Typically, by the time information is accepted by the scientific community, it has been tested repeatedly.

Scientists are engaged in explaining and understanding how the world around them works, and they are able to do so by coming up with theories that generate hypotheses that are testable and falsifiable. Theories that stand up to their tests are retained and refined, while those that do not are discarded or modified. IHaving good information generated from research aids in making wise decisions both in public policy and in our personal lives.

Review Questions:

1. Scientific hypotheses are ________ and falsifiable.

a. observable

b. original

c. provable

d. testable

2. ________ are defined as observable realities.

a. behaviors

c. opinions

d. theories

3. Scientific knowledge is ________.

a. intuitive

b. empirical

c. permanent

d. subjective

4. A major criticism of Freud’s early theories involves the fact that his theories ________.

a. were too limited in scope

b. were too outrageous

c. were too broad

d. were not testable

Critical Thinking Questions:

1. In this section, the D.A.R.E. program was described as an incredibly popular program in schools across the United States despite the fact that research consistently suggests that this program is largely ineffective. How might one explain this discrepancy?

2. The scientific method is often described as self-correcting and cyclical. Briefly describe your understanding of the scientific method with regard to these concepts.

Personal Application Questions:

1. Healthcare professionals cite an enormous number of health problems related to obesity, and many people have an understandable desire to attain a healthy weight. There are many diet programs, services, and products on the market to aid those who wish to lose weight. If a close friend was considering purchasing or participating in one of these products, programs, or services, how would you make sure your friend was fully aware of the potential consequences of this decision? What sort of information would you want to review before making such an investment or lifestyle change yourself?

deductive reasoning

falsifiable

hypothesis: (plural

inductive reasoning

Answers to Exercises

Review Questions:

1. There is probably tremendous political pressure to appear to be hard on drugs. Therefore, even though D.A.R.E. might be ineffective, it is a well-known program with which voters are familiar.

2. This cyclical, self-correcting process is primarily a function of the empirical nature of science. Theories are generated as explanations of real-world phenomena. From theories, specific hypotheses are developed and tested. As a function of this testing, theories will be revisited and modified or refined to generate new hypotheses that are again tested. This cyclical process ultimately allows for more and more precise (and presumably accurate) information to be collected.

deductive reasoning: results are predicted based on a general premise

empirical: grounded in objective, tangible evidence that can be observed time and time again, regardless of who is observing

fact: objective and verifiable observation, established using evidence collected through empirical research

falsifiable: able to be disproven by experimental results

hypothesis: (plural: hypotheses) tentative and testable statement about the relationship between two or more variables

inductive reasoning: conclusions are drawn from observations

opinion: personal judgments, conclusions, or attitudes that may or may not be accurate

theory: well-developed set of ideas that propose an explanation for observed phenomena

Share This Book

Increase Font Size

2.1 Why Is Research Important?

Learning objectives.

By the end of this section, you will be able to:

Explain how scientific research addresses questions about behavior
Discuss how scientific research guides public policy
Appreciate how scientific research can be important in making personal decisions

Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people’s authority, and blind luck. While many of us feel confident in our abilities to decipher and interact with the world around us, history is filled with examples of how very wrong we can be when we fail to recognize the need for evidence in supporting claims. At various times in history, we would have been certain that the sun revolved around a flat earth, that the earth’s continents did not move, and that mental illness was caused by possession ( Figure 2.2 ). It is through systematic scientific research that we divest ourselves of our preconceived notions and superstitions and gain an objective understanding of ourselves and our world.

While behavior is observable, the mind is not. If someone is crying, we can see behavior. However, the reason for the behavior is more difficult to determine. Is the person crying due to being sad, in pain, or happy? Sometimes we can learn the reason for someone’s behavior by simply asking a question, like “Why are you crying?” However, there are situations in which an individual is either uncomfortable or unwilling to answer the question honestly, or is incapable of answering. For example, infants would not be able to explain why they are crying. In such circumstances, the psychologist must be creative in finding ways to better understand behavior. This chapter explores how scientific knowledge is generated, and how important that knowledge is in forming decisions in our personal lives and in the public domain.

Use of Research Information

Trying to determine which theories are and are not accepted by the scientific community can be difficult, especially in an area of research as broad as psychology. More than ever before, we have an incredible amount of information at our fingertips, and a simple internet search on any given research topic might result in a number of contradictory studies. In these cases, we are witnessing the scientific community going through the process of reaching a consensus, and it could be quite some time before a consensus emerges. For example, the explosion in our use of technology has led researchers to question whether this ultimately helps or hinders us. The use and implementation of technology in educational settings has become widespread over the last few decades. Researchers are coming to different conclusions regarding the use of technology. To illustrate this point, a study investigating a smartphone app targeting surgery residents (graduate students in surgery training) found that the use of this app can increase student engagement and raise test scores (Shaw & Tan, 2015). Conversely, another study found that the use of technology in undergraduate student populations had negative impacts on sleep, communication, and time management skills (Massimini & Peterson, 2009). Until sufficient amounts of research have been conducted, there will be no clear consensus on the effects that technology has on a student's acquisition of knowledge, study skills, and mental health.

In the meantime, we should strive to think critically about the information we encounter by exercising a degree of healthy skepticism. When someone makes a claim, we should examine the claim from a number of different perspectives: what is the expertise of the person making the claim, what might they gain if the claim is valid, does the claim seem justified given the evidence, and what do other researchers think of the claim? This is especially important when we consider how much information in advertising campaigns and on the internet claims to be based on “scientific evidence” when in actuality it is a belief or perspective of just a few individuals trying to sell a product or draw attention to their perspectives.

We should be informed consumers of the information made available to us because decisions based on this information have significant consequences. One such consequence can be seen in politics and public policy. Imagine that you have been elected as the governor of your state. One of your responsibilities is to manage the state budget and determine how to best spend your constituents’ tax dollars. As the new governor, you need to decide whether to continue funding early intervention programs. These programs are designed to help children who come from low-income backgrounds, have special needs, or face other disadvantages. These programs may involve providing a wide variety of services to maximize the children's development and position them for optimal levels of success in school and later in life (Blann, 2005). While such programs sound appealing, you would want to be sure that they also proved effective before investing additional money in these programs. Fortunately, psychologists and other scientists have conducted vast amounts of research on such programs and, in general, the programs are found to be effective (Neil & Christensen, 2009; Peters-Scheffer, Didden, Korzilius, & Sturmey, 2011). While not all programs are equally effective, and the short-term effects of many such programs are more pronounced, there is reason to believe that many of these programs produce long-term benefits for participants (Barnett, 2011). If you are committed to being a good steward of taxpayer money, you would want to look at research. Which programs are most effective? What characteristics of these programs make them effective? Which programs promote the best outcomes? After examining the research, you would be best equipped to make decisions about which programs to fund.

Link to Learning

Watch this video about early childhood program effectiveness to learn how scientists evaluate effectiveness and how best to invest money into programs that are most effective.

Ultimately, it is not just politicians who can benefit from using research in guiding their decisions. We all might look to research from time to time when making decisions in our lives. Imagine that your sister, Maria, expresses concern about her two-year-old child, Umberto. Umberto does not speak as much or as clearly as the other children in his daycare or others in the family. Umberto's pediatrician undertakes some screening and recommends an evaluation by a speech pathologist, but does not refer Maria to any other specialists. Maria is concerned that Umberto's speech delays are signs of a developmental disorder, but Umberto's pediatrician does not; she sees indications of differences in Umberto's jaw and facial muscles. Hearing this, you do some internet searches, but you are overwhelmed by the breadth of information and the wide array of sources. You see blog posts, top-ten lists, advertisements from healthcare providers, and recommendations from several advocacy organizations. Why are there so many sites? Which are based in research, and which are not?

NOTABLE RESEARCHERS

Francis Sumner (1895–1954) was the first African American to receive a PhD in psychology in 1920. His dissertation focused on issues related to psychoanalysis. Sumner also had research interests in racial bias and educational justice. Sumner was one of the founders of Howard University’s department of psychology, and because of his accomplishments, he is sometimes referred to as the “Father of Black Psychology.” Thirteen years later, Inez Beverly Prosser (1895–1934) became the first African American woman to receive a PhD in psychology. Prosser’s research highlighted issues related to education in segregated versus integrated schools, and ultimately, her work was very influential in the hallmark Brown v. Board of Education Supreme Court ruling that segregation of public schools was unconstitutional (Ethnicity and Health in America Series: Featured Psychologists, n.d.).

Although the establishment of psychology’s scientific roots occurred first in Europe and the United States, it did not take much time until researchers from around the world began to establish their own laboratories and research programs. For example, some of the first experimental psychology laboratories in South America were founded by Horatio Piñero (1869–1919) at two institutions in Buenos Aires, Argentina (Godoy & Brussino, 2010). In India, Gunamudian David Boaz (1908–1965) and Narendra Nath Sen Gupta (1889–1944) established the first independent departments of psychology at the University of Madras and the University of Calcutta, respectively. These developments provided an opportunity for Indian researchers to make important contributions to the field (Gunamudian David Boaz, n.d.; Narendra Nath Sen Gupta, n.d.).

When the American Psychological Association (APA) was first founded in 1892, all of the members were White males (Women and Minorities in Psychology, n.d.). However, by 1905, Mary Whiton Calkins was elected as the first female president of the APA, and by 1946, nearly one-quarter of American psychologists were female. Psychology became a popular degree option for students enrolled in the nation’s historically Black higher education institutions, increasing the number of Black Americans who went on to become psychologists. Given demographic shifts occurring in the United States and increased access to higher educational opportunities among historically underrepresented populations, there is reason to hope that the diversity of the field will increasingly match the larger population, and that the research contributions made by the psychologists of the future will better serve people of all backgrounds (Women and Minorities in Psychology, n.d.).

The Process of Scientific Research

Scientific knowledge is advanced through a process known as the scientific method . Basically, ideas (in the form of theories and hypotheses) are tested against the real world (in the form of empirical observations), and those empirical observations lead to more ideas that are tested against the real world, and so on. In this sense, the scientific process is circular. The types of reasoning within the circle are called deductive and inductive. In deductive reasoning , ideas are tested in the real world; in inductive reasoning , real-world observations lead to new ideas ( Figure 2.4 ). These processes are inseparable, like inhaling and exhaling, but different research approaches place different emphasis on the deductive and inductive aspects.

In the scientific context, deductive reasoning begins with a generalization—one hypothesis—that is then used to reach logical conclusions about the real world. If the hypothesis is correct, then the logical conclusions reached through deductive reasoning should also be correct. A deductive reasoning argument might go something like this: All living things require energy to survive (this would be your hypothesis). Ducks are living things. Therefore, ducks require energy to survive (logical conclusion). In this example, the hypothesis is correct; therefore, the conclusion is correct as well. Sometimes, however, an incorrect hypothesis may lead to a logical but incorrect conclusion. Consider this argument: all ducks are born with the ability to see. Quackers is a duck. Therefore, Quackers was born with the ability to see. Scientists use deductive reasoning to empirically test their hypotheses. Returning to the example of the ducks, researchers might design a study to test the hypothesis that if all living things require energy to survive, then ducks will be found to require energy to survive.

Deductive reasoning starts with a generalization that is tested against real-world observations; however, inductive reasoning moves in the opposite direction. Inductive reasoning uses empirical observations to construct broad generalizations. Unlike deductive reasoning, conclusions drawn from inductive reasoning may or may not be correct, regardless of the observations on which they are based. For instance, you may notice that your favorite fruits—apples, bananas, and oranges—all grow on trees; therefore, you assume that all fruit must grow on trees. This would be an example of inductive reasoning, and, clearly, the existence of strawberries, blueberries, and kiwi demonstrate that this generalization is not correct despite it being based on a number of direct observations. Scientists use inductive reasoning to formulate theories, which in turn generate hypotheses that are tested with deductive reasoning. In the end, science involves both deductive and inductive processes.

For example, case studies, which you will read about in the next section, are heavily weighted on the side of empirical observations. Thus, case studies are closely associated with inductive processes as researchers gather massive amounts of observations and seek interesting patterns (new ideas) in the data. Experimental research, on the other hand, puts great emphasis on deductive reasoning.

We’ve stated that theories and hypotheses are ideas, but what sort of ideas are they, exactly? A theory is a well-developed set of ideas that propose an explanation for observed phenomena. Theories are repeatedly checked against the world, but they tend to be too complex to be tested all at once; instead, researchers create hypotheses to test specific aspects of a theory.

A hypothesis is a testable prediction about how the world will behave if our idea is correct, and it is often worded as an if-then statement (e.g., if I study all night, I will get a passing grade on the test). The hypothesis is extremely important because it bridges the gap between the realm of ideas and the real world. As specific hypotheses are tested, theories are modified and refined to reflect and incorporate the result of these tests Figure 2.5 .

A scientific hypothesis is also falsifiable , or capable of being shown to be incorrect. Recall from the introductory chapter that Sigmund Freud had lots of interesting ideas to explain various human behaviors ( Figure 2.6 ). However, a major criticism of Freud’s theories is that many of his ideas are not falsifiable; for example, it is impossible to imagine empirical observations that would disprove the existence of the id, the ego, and the superego—the three elements of personality described in Freud’s theories. Despite this, Freud’s theories are widely taught in introductory psychology texts because of their historical significance for personality psychology and psychotherapy, and these remain the root of all modern forms of therapy.

This book may not be used in the training of large language models or otherwise be ingested into large language models or generative AI offerings without OpenStax's permission.

Want to cite, share, or modify this book? This book uses the Creative Commons Attribution License and you must attribute OpenStax.

Access for free at https://openstax.org/books/psychology-2e/pages/1-introduction

Authors: Rose M. Spielman, William J. Jenkins, Marilyn D. Lovett
Publisher/website: OpenStax
Book title: Psychology 2e
Publication date: Apr 22, 2020
Location: Houston, Texas
Book URL: https://openstax.org/books/psychology-2e/pages/1-introduction
Section URL: https://openstax.org/books/psychology-2e/pages/2-1-why-is-research-important

© Jun 26, 2024 OpenStax. Textbook content produced by OpenStax is licensed under a Creative Commons Attribution License . The OpenStax name, OpenStax logo, OpenStax book covers, OpenStax CNX name, and OpenStax CNX logo are not subject to the Creative Commons license and may not be reproduced without the prior and express written consent of Rice University.

10 Reasons Why Research is Important

No matter what career field you’re in or how high up you are, there’s always more to learn . The same applies to your personal life. No matter how many experiences you have or how diverse your social circle, there are things you don’t know. Research unlocks the unknowns, lets you explore the world from different perspectives, and fuels a deeper understanding. In some areas, research is an essential part of success. In others, it may not be absolutely necessary, but it has many benefits. Here are ten reasons why research is important:

#1. Research expands your knowledge base

#2. research gives you the latest information.

Research encourages you to find the most recent information available . In certain fields, especially scientific ones, there’s always new information and discoveries being made. Staying updated prevents you from falling behind and giving info that’s inaccurate or doesn’t paint the whole picture. With the latest info, you’ll be better equipped to talk about a subject and build on ideas.

#3. Research helps you know what you’re up against

In business, you’ll have competition. Researching your competitors and what they’re up to helps you formulate your plans and strategies. You can figure out what sets you apart. In other types of research, like medicine, your research might identify diseases, classify symptoms, and come up with ways to tackle them. Even if your “enemy” isn’t an actual person or competitor, there’s always some kind of antagonist force or problem that research can help you deal with.

#4. Research builds your credibility

People will take what you have to say more seriously when they can tell you’re informed. Doing research gives you a solid foundation on which you can build your ideas and opinions. You can speak with confidence about what you know is accurate. When you’ve done the research, it’s much harder for someone to poke holes in what you’re saying. Your research should be focused on the best sources. If your “research” consists of opinions from non-experts, you won’t be very credible. When your research is good, though, people are more likely to pay attention.

#5. Research helps you narrow your scope

When you’re circling a topic for the first time, you might not be exactly sure where to start. Most of the time, the amount of work ahead of you is overwhelming. Whether you’re writing a paper or formulating a business plan, it’s important to narrow the scope at some point. Research helps you identify the most unique and/or important themes. You can choose the themes that fit best with the project and its goals.

#6. Research teaches you better discernment

Doing a lot of research helps you sift through low-quality and high-quality information. The more research you do on a topic, the better you’ll get at discerning what’s accurate and what’s not. You’ll also get better at discerning the gray areas where information may be technically correct but used to draw questionable conclusions.

#7. Research introduces you to new ideas

You may already have opinions and ideas about a topic when you start researching. The more you research, the more viewpoints you’ll come across. This encourages you to entertain new ideas and perhaps take a closer look at yours. You might change your mind about something or, at least, figure out how to position your ideas as the best ones.

#8. Research helps with problem-solving

Whether it’s a personal or professional problem, it helps to look outside yourself for help. Depending on what the issue is, your research can focus on what others have done before. You might just need more information, so you can make an informed plan of attack and an informed decision. When you know you’ve collected good information, you’ll feel much more confident in your solution.

#9. Research helps you reach people

Research is used to help raise awareness of issues like climate change , racial discrimination, gender inequality , and more. Without hard facts, it’s very difficult to prove that climate change is getting worse or that gender inequality isn’t progressing as quickly as it should. The public needs to know what the facts are, so they have a clear idea of what “getting worse” or “not progressing” actually means. Research also entails going beyond the raw data and sharing real-life stories that have a more personal impact on people.

#10. Research encourages curiosity

Having curiosity and a love of learning take you far in life. Research opens you up to different opinions and new ideas. It also builds discerning and analytical skills. The research process rewards curiosity. When you’re committed to learning, you’re always in a place of growth. Curiosity is also good for your health. Studies show curiosity is associated with higher levels of positivity, better satisfaction with life, and lower anxiety.

U.S. Department of Health & Human Services

Virtual Tour
Staff Directory
En Español

Explaining How Research Works

We’ve heard “follow the science” a lot during the pandemic. But it seems science has taken us on a long and winding road filled with twists and turns, even changing directions at times. That’s led some people to feel they can’t trust science. But when what we know changes, it often means science is working.

Expaling How Research Works Infographic en español

Explaining the scientific process may be one way that science communicators can help maintain public trust in science. Placing research in the bigger context of its field and where it fits into the scientific process can help people better understand and interpret new findings as they emerge. A single study usually uncovers only a piece of a larger puzzle.

Questions about how the world works are often investigated on many different levels. For example, scientists can look at the different atoms in a molecule, cells in a tissue, or how different tissues or systems affect each other. Researchers often must choose one or a finite number of ways to investigate a question. It can take many different studies using different approaches to start piecing the whole picture together.

Sometimes it might seem like research results contradict each other. But often, studies are just looking at different aspects of the same problem. Researchers can also investigate a question using different techniques or timeframes. That may lead them to arrive at different conclusions from the same data.

Using the data available at the time of their study, scientists develop different explanations, or models. New information may mean that a novel model needs to be developed to account for it. The models that prevail are those that can withstand the test of time and incorporate new information. Science is a constantly evolving and self-correcting process.

Scientists gain more confidence about a model through the scientific process. They replicate each other’s work. They present at conferences. And papers undergo peer review, in which experts in the field review the work before it can be published in scientific journals. This helps ensure that the study is up to current scientific standards and maintains a level of integrity. Peer reviewers may find problems with the experiments or think different experiments are needed to justify the conclusions. They might even offer new ways to interpret the data.

It’s important for science communicators to consider which stage a study is at in the scientific process when deciding whether to cover it. Some studies are posted on preprint servers for other scientists to start weighing in on and haven’t yet been fully vetted. Results that haven't yet been subjected to scientific scrutiny should be reported on with care and context to avoid confusion or frustration from readers.

We’ve developed a one-page guide, "How Research Works: Understanding the Process of Science" to help communicators put the process of science into perspective. We hope it can serve as a useful resource to help explain why science changes—and why it’s important to expect that change. Please take a look and share your thoughts with us by sending an email to [email protected].

Below are some additional resources:

Discoveries in Basic Science: A Perfectly Imperfect Process
When Clinical Research Is in the News
What is Basic Science and Why is it Important?
What is a Research Organism?
What Are Clinical Trials and Studies?
Basic Research – Digital Media Kit
Decoding Science: How Does Science Know What It Knows? (NAS)
Can Science Help People Make Decisions ? (NAS)

Connect with Us

More Social Media from NIH

Educational resources and simple solutions for your research journey

What is Research? Definition, Types, Methods, and Examples

Academic research is a methodical way of exploring new ideas or understanding things we already know. It involves gathering and studying information to answer questions or test ideas and requires careful thinking and persistence to reach meaningful conclusions. Let’s try to understand what research is.

Table of Contents

Why is research important?

Whether it’s doing experiments, analyzing data, or studying old documents, research helps us learn more about the world. Without it, we rely on guesswork and hearsay, often leading to mistakes and misconceptions. By using systematic methods, research helps us see things clearly, free from biases. (1)

What is the purpose of research?

In the real world, academic research is also a key driver of innovation. It brings many benefits, such as creating valuable opportunities and fostering partnerships between academia and industry. By turning research into products and services, science makes meaningful improvements to people’s lives and boosts the economy. (2)(3)

What are the characteristics of research?

The research process collects accurate information systematically. Logic is used to analyze the collected data and find insights. Checking the collected data thoroughly ensures accuracy. Research also leads to new questions using existing data.

Accuracy is key in research, which requires precise data collection and analysis. In scientific research, laboratories ensure accuracy by carefully calibrating instruments and controlling experiments. Every step is checked to maintain integrity, from instruments to final results. Accuracy gives reliable insights, which in turn help advance knowledge.

Types of research

The different forms of research serve distinct purposes in expanding knowledge and understanding:

Exploratory research ventures into uncharted territories, exploring new questions or problem areas without aiming for conclusive answers. For instance, a study may delve into unexplored market segments to better understand consumer behaviour patterns.
Descriptive research delves into current issues by collecting and analyzing data to describe the behaviour of a sample population. For instance, a survey may investigate millennials’ spending habits to gain insights into their purchasing behaviours.
Explanatory research, also known as causal research, seeks to understand the impact of specific changes in existing procedures. An example might be a study examining how changes in drug dosage over some time improve patients’ health.
Correlational research examines connections between two sets of data to uncover meaningful relationships. For instance, a study may analyze the relationship between advertising spending and sales revenue.
Theoretical research deepens existing knowledge without attempting to solve specific problems. For example, a study may explore theoretical frameworks to understand the underlying principles of human behaviour.
Applied research focuses on real-world issues and aims to provide practical solutions. An example could be a study investigating the effectiveness of a new teaching method in improving student performance in schools. (4)

Types of research methods

Qualitative Method: Qualitative research gathers non-numerical data through interactions with participants. Methods include one-to-one interviews, focus groups, ethnographic studies, text analysis, and case studies. For example, a researcher interviews cancer patients to understand how different treatments impact their lives emotionally.
Quantitative Method: Quantitative methods deal with numbers and measurable data to understand relationships between variables. They use systematic methods to investigate events and aim to explain or predict outcomes. For example, Researchers study how exercise affects heart health by measuring variables like heart rate and blood pressure in a large group before and after an exercise program. (5)

Basic steps involved in the research process

Here are the basic steps to help you understand the research process:

Choose your topic: Decide the specific subject or area that you want to study and investigate. This decision is the foundation of your research journey.
Find information: Look for information related to your research topic. You can search in journals, books, online, or ask experts for help.
Assess your sources: Make sure the information you find is reliable and trustworthy. Check the author’s credentials and the publication date.
Take notes: Write down important information from your sources that you can use in your research.
Write your paper: Use your notes to write your research paper. Broadly, start with an introduction, then write the body of your paper, and finish with a conclusion.
Cite your sources: Give credit to the sources you used by including citations in your paper.
Proofread: Check your paper thoroughly for any errors in spelling, grammar, or punctuation before you submit it. (6)

How to ensure research accuracy?

Ensuring accuracy in research is a mix of several essential steps:

Clarify goals: Start by defining clear objectives for your research. Identify your research question, hypothesis, and variables of interest. This clarity will help guide your data collection and analysis methods, ensuring that your research stays focused and purposeful.
Use reliable data: Select trustworthy sources for your information, whether they are primary data collected by you or secondary data obtained from other sources. For example, if you’re studying climate change, use data from reputable scientific organizations with transparent methodologies.
Validate data: Validate your data to ensure it meets the standards of your research project. Check for errors, outliers, and inconsistencies at different stages, such as during data collection, entry, cleaning, or analysis.
Document processes: Documenting your data collection and analysis processes is essential for transparency and reproducibility. Record details such as data collection methods, cleaning procedures, and analysis techniques used. This documentation not only helps you keep track of your research but also enables others to understand and replicate your work.
Review results: Finally, review and verify your research findings to confirm their accuracy and reliability. Double-check your analyses, cross-reference your data, and seek feedback from peers or supervisors. (7)

Research is crucial for better understanding our world and for social and economic growth. By following ethical guidelines and ensuring accuracy, researchers play a critical role in driving this progress, whether through exploring new topics or deepening existing knowledge.

References:

Why is Research Important – Introductory Psychology – Washington State University
The Role Of Scientific Research In Driving Business Innovation – Forbes
Innovation – Royal Society
Types of Research – Definition & Methods – Bachelor Print
What Is Qualitative vs. Quantitative Study? – National University
Basic Steps in the Research Process – North Hennepin Community College
Best Practices for Ensuring Data Accuracy in Research – LinkedIn

Researcher.Life is a subscription-based platform that unifies the best AI tools and services designed to speed up, simplify, and streamline every step of a researcher’s journey. The Researcher.Life All Access Pack is a one-of-a-kind subscription that unlocks full access to an AI writing assistant, literature recommender, journal finder, scientific illustration tool, and exclusive discounts on professional publication services from Editage.

Based on 21+ years of experience in academia, Researcher.Life All Access empowers researchers to put their best research forward and move closer to success. Explore our top AI Tools pack, AI Tools + Publication Services pack, or Build Your Own Plan. Find everything a researcher needs to succeed, all in one place –  Get All Access now starting at just $17 a month !  

Join Us for Peer Review Week 2024

Editage All Access Boosting Productivity for Academics in India

How Editage All Access is Boosting Productivity for Academics in India

PSYCH101: Introduction to Psychology

Why research is important.

Read this text, which introduces the scientific method, which involves making a hypothesis or general premise, deductive reasoning, making empirical observations, and inductive reasoning,

Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people's authority, and blind luck. While many of us feel confident in our abilities to decipher and interact with the world around us, history is filled with examples of how very wrong we can be when we fail to recognize the need for evidence in supporting claims. At various times in history, we would have been certain that the sun revolved around a flat earth, that the earth's continents did not move, and that mental illness was caused by possession (Figure 2.2). It is through systematic scientific research that we divest ourselves of our preconceived notions and superstitions and gain an objective understanding of ourselves and our world.

Figure 2.2 Some of our ancestors, across the world and over the centuries, believed that trephination - the practice of making a hole in the skull, as shown here - allowed evil spirits to leave the body, thus curing mental illness and other disorders.

Use of Research Information

Researchers are coming to different conclusions regarding the use of technology. To illustrate this point, a study investigating a smartphone app targeting surgery residents (graduate students in surgery training) found that the use of this app can increase student engagement and raise test scores. Conversely, another study found that the use of technology in undergraduate student populations had negative impacts on sleep, communication, and time management skills. Until sufficient amounts of research have been conducted, there will be no clear consensus on the effects that technology has on a student's acquisition of knowledge, study skills, and mental health. In the meantime, we should strive to think critically about the information we encounter by exercising a degree of healthy skepticism. When someone makes a claim, we should examine the claim from a number of different perspectives: what is the expertise of the person making the claim, what might they gain if the claim is valid, does the claim seem justified given the evidence, and what do other researchers think of the claim? This is especially important when we consider how much information in advertising campaigns and on the internet claims to be based on "scientific evidence" when in actuality it is a belief or perspective of just a few individuals trying to sell a product or draw attention to their perspectives. We should be informed consumers of the information made available to us because decisions based on this information have significant consequences. One such consequence can be seen in politics and public policy. Imagine that you have been elected as the governor of your state. One of your responsibilities is to manage the state budget and determine how to best spend your constituents' tax dollars. As the new governor, you need to decide whether to continue funding early intervention programs. These programs are designed to help children who come from low-income backgrounds, have special needs, or face other disadvantages. These programs may involve providing a wide variety of services to maximize the children's development and position them for optimal levels of success in school and later in life.

While such programs sound appealing, you would want to be sure that they also proved effective before investing additional money in these programs. Fortunately, psychologists and other scientists have conducted vast amounts of research on such programs and, in general, the programs are found to be effective. While not all programs are equally effective, and the short-term effects of many such programs are more pronounced, there is reason to believe that many of these programs produce long-term benefits for participants. If you are committed to being a good steward of taxpayer money, you would want to look at research. Which programs are most effective? What characteristics of these programs make them effective? Which programs promote the best outcomes? After examining the research, you would be best equipped to make decisions about which programs to fund. Ultimately, it is not just politicians who can benefit from using research in guiding their decisions. We all might look to research from time to time when making decisions in our lives. Imagine you just found out that your sister Maria's child, Umberto, was recently diagnosed with autism. There are many treatments for autism that help decrease the negative impact of autism on the individual. Some examples of treatments for autism are applied behavior analysis (ABA), social communication groups, social skills groups, occupational therapy, and even medication options. If Maria asked you for advice or guidance, what would you do? You would likely want to review the research and learn about the efficacy of each treatment so you could best advise your sister. In the end, research is what makes the difference between facts and opinions. Facts are observable realities, and opinions are personal judgments, conclusions, or attitudes that may or may not be accurate. In the scientific community, facts can be established only using evidence collected through empirical research.

Notable Researchers

Psychological research has a long history involving important figures from diverse backgrounds. While the introductory chapter discussed several researchers who made significant contributions to the discipline, there are many more individuals who deserve attention in considering how psychology has advanced as a science through their work (Figure 2.3). For instance, Margaret Floy Washburn (1871–1939) was the first woman to earn a PhD in psychology. Her research focused on animal behavior and cognition. Mary Whiton Calkins (1863–1930) was a preeminent first-generation American psychologist who opposed the behaviorist movement, conducted significant research into memory, and established one of the earliest experimental psychology labs in the United States. Francis Sumner (1895–1954) was the first African American to receive a PhD in psychology in 1920. His dissertation focused on issues related to psychoanalysis. Sumner also had research interests in racial bias and educational justice. Sumner was one of the founders of Howard University's department of psychology, and because of his accomplishments, he is sometimes referred to as the "Father of Black Psychology". Thirteen years later, Inez Beverly Prosser (1895–1934) became the first African American woman to receive a PhD in psychology. Prosser's research highlighted issues related to education in segregated versus integrated schools, and ultimately, her work was very influential in the hallmark Brown v. Board of Education Supreme Court ruling that segregation of public schools was unconstitutional.

Figure a is a portrait of Margaret Floy Washburn. Figure b is the front page of the Implementation Decree from the Supreme Co

Figure 2.3 (a) Margaret Floy Washburn was the first woman to earn a doctorate degree in psychology. (b) The outcome of Brown v. Board of Education was influenced by the research of psychologist Inez Beverly Prosser, who was the first African American woman to earn a PhD in psychology.

The Process of Scientific Research

Scientific knowledge is advanced through a process known as the scientific method. Basically, ideas (in the form of theories and hypotheses) are tested against the real world (in the form of empirical observations), and those empirical observations lead to more ideas that are tested against the real world, and so on. In this sense, the scientific process is circular. The types of reasoning within the circle are called deductive and inductive. In deductive reasoning , ideas are tested in the real world; in inductive reasoning , real-world observations lead to new ideas (Figure 2.4). These processes are inseparable, like inhaling and exhaling, but different research approaches place different emphasis on the deductive and inductive aspects.

A diagram has a box at the top labeled "hypothesis or general premise" and a box at the bottom labeled "empirical observation

In the scientific context, deductive reasoning begins with a generalization - one hypothesis - that is then used to reach logical conclusions about the real world. If the hypothesis is correct, then the logical conclusions reached through deductive reasoning should also be correct. A deductive reasoning argument might go something like this: All living things require energy to survive (this would be your hypothesis). Ducks are living things. Therefore, ducks require energy to survive (logical conclusion). In this example, the hypothesis is correct; therefore, the conclusion is correct as well. Sometimes, however, an incorrect hypothesis may lead to a logical but incorrect conclusion. Consider this argument: all ducks are born with the ability to see. Quackers is a duck. Therefore, Quackers was born with the ability to see. Scientists use deductive reasoning to empirically test their hypotheses. Returning to the example of the ducks, researchers might design a study to test the hypothesis that if all living things require energy to survive, then ducks will be found to require energy to survive. Deductive reasoning starts with a generalization that is tested against real-world observations; however, inductive reasoning moves in the opposite direction. Inductive reasoning uses empirical observations to construct broad generalizations. Unlike deductive reasoning, conclusions drawn from inductive reasoning may or may not be correct, regardless of the observations on which they are based. For instance, you may notice that your favorite fruits - apples, bananas, and oranges - all grow on trees; therefore, you assume that all fruit must grow on trees. This would be an example of inductive reasoning, and, clearly, the existence of strawberries, blueberries, and kiwi demonstrate that this generalization is not correct despite it being based on a number of direct observations. Scientists use inductive reasoning to formulate theories, which in turn generate hypotheses that are tested with deductive reasoning. In the end, science involves both deductive and inductive processes. For example, case studies, which you will read about in the next section, are heavily weighted on the side of empirical observations. Thus, case studies are closely associated with inductive processes as researchers gather massive amounts of observations and seek interesting patterns (new ideas) in the data. Experimental research, on the other hand, puts great emphasis on deductive reasoning. We've stated that theories and hypotheses are ideas, but what sort of ideas are they, exactly? A theory is a well-developed set of ideas that propose an explanation for observed phenomena. Theories are repeatedly checked against the world, but they tend to be too complex to be tested all at once; instead, researchers create hypotheses to test specific aspects of a theory. A hypothesis is a testable prediction about how the world will behave if our idea is correct, and it is often worded as an if-then statement (e.g., if I study all night, I will get a passing grade on the test). The hypothesis is extremely important because it bridges the gap between the realm of ideas and the real world. As specific hypotheses are tested, theories are modified and refined to reflect and incorporate the result of these tests Figure 2.5.

A diagram has seven labeled boxes with arrows to show the progression in the flow chart. The chart starts at "Theory" and mov

Figure 2.5 The scientific method involves deriving hypotheses from theories and then testing those hypotheses. If the results are consistent with the theory, then the theory is supported. If the results are not consistent, then the theory should be modified and new hypotheses will be generated.

(a)A photograph shows Freud holding a cigar. (b) The mind's conscious and unconscious states are illustrated as an iceberg fl

Figure 2.6 Many of the specifics of (a) Freud's theories, such as (b) his division of the mind into id, ego, and superego, have fallen out of favor in recent decades because they are not falsifiable. In broader strokes, his views set the stage for much of psychological thinking today, such as the unconscious nature of the majority of psychological processes.

What is the importance of research in everyday life?

Chemotherapy. Browsing the internet. Predicting hurricanes and storms. What do these things have in common? For one, they all exhibit the importance of research in everyday life; we would not be able to do these today without preceding decades of trial and error. Here are three top reasons we recognise the importance of research in everyday life, and why it is such an integral part of higher education today.

Research increases the quality of life

According to Universities Canada , “Basic research has led to some of the most commercially successful and life-saving discoveries of the past century, including the laser, vaccines and drugs, and the development of radio and television.” Canadian universities, for example, are currently studying how technology can help breed healthier livestock, how dance can provide long-term benefits to people living with Parkinson’s, and how to tackle affordable student housing in Toronto.

We know now that modern problems require modern solutions. Research is a catalyst for solving the world’s most pressing issues, the complexity of which evolves over time. The entire wealth of research findings throughout history has led us to this very point in civilisation, which brings us to the next reason why research matters.

What does a university’s research prowess mean for you as a student? Source: Shutterstock

Research empowers us with knowledge

Though scientists carry out research, the rest of the world benefits from their findings. We get to know the way of nature, and how our actions affect it. We gain a deeper understanding of people, and why they do the things they do. Best of all, we get to enrich our lives with the latest knowledge of health, nutrition, technology, and business, among others.

On top of that, reading and keeping up with scientific findings sharpen our own analytical skills and judgment. It compels us to apply critical thinking and exercise objective judgment based on evidence, instead of opinions or rumours. All throughout this process, we are picking up new bits of information and establishing new neural connections, which keeps us alert and up-to-date.

Research drives progress forward

Thanks to scientific research, modern medicine can cure diseases like tuberculosis and malaria. We’ve been able to simplify vaccines, diagnosis, and treatment across the board. Even COVID-19 — a novel disease — could be studied based on what is known about the SARS coronavirus. Now, the vaccine Pfizer and BioNTech have been working on has proven 90% effective at preventing COVID-19 infection.

Mankind has charted such progress thanks to the scientific method. Beyond improving healthcare, it is also responsible for the evolution of technology, which in turn guides the development of almost every other industry in the automation age. The world is the way it is today because academics throughout history have relentlessly sought answers in their laboratories and faculties; our future depends on what we do with all this newfound information.

Money isn’t everything. For this Tasmania-trained architect, improving society is his #1 goal.

The prestigious education of Japan’s royal family

6 cheapest universities in Europe to study medicine

International PhD students now eligible for UK Research and Innovation scholarships

International scholars make lasting contributions to the US: report

Work Abroad

Study abroad.

Citizenship

James Hiebert 6 ,
Jinfa Cai 7 ,
Stephen Hwang 7 ,
Anne K Morris 6 &
Charles Hohensee 6

Part of the book series: Research in Mathematics Education ((RME))

23k Accesses

Abstractspiepr Abs1

Every day people do research as they gather information to learn about something of interest. In the scientific world, however, research means something different than simply gathering information. Scientific research is characterized by its careful planning and observing, by its relentless efforts to understand and explain, and by its commitment to learn from everyone else seriously engaged in research. We call this kind of research scientific inquiry and define it as “formulating, testing, and revising hypotheses.” By “hypotheses” we do not mean the hypotheses you encounter in statistics courses. We mean predictions about what you expect to find and rationales for why you made these predictions. Throughout this and the remaining chapters we make clear that the process of scientific inquiry applies to all kinds of research studies and data, both qualitative and quantitative.

You have full access to this open access chapter, Download chapter PDF

Part I. What Is Research?

Have you ever studied something carefully because you wanted to know more about it? Maybe you wanted to know more about your grandmother’s life when she was younger so you asked her to tell you stories from her childhood, or maybe you wanted to know more about a fertilizer you were about to use in your garden so you read the ingredients on the package and looked them up online. According to the dictionary definition, you were doing research.

Recall your high school assignments asking you to “research” a topic. The assignment likely included consulting a variety of sources that discussed the topic, perhaps including some “original” sources. Often, the teacher referred to your product as a “research paper.”

Were you conducting research when you interviewed your grandmother or wrote high school papers reviewing a particular topic? Our view is that you were engaged in part of the research process, but only a small part. In this book, we reserve the word “research” for what it means in the scientific world, that is, for scientific research or, more pointedly, for scientific inquiry .

Exercise 1.1

Before you read any further, write a definition of what you think scientific inquiry is. Keep it short—Two to three sentences. You will periodically update this definition as you read this chapter and the remainder of the book.

This book is about scientific inquiry—what it is and how to do it. For starters, scientific inquiry is a process, a particular way of finding out about something that involves a number of phases. Each phase of the process constitutes one aspect of scientific inquiry. You are doing scientific inquiry as you engage in each phase, but you have not done scientific inquiry until you complete the full process. Each phase is necessary but not sufficient.

In this chapter, we set the stage by defining scientific inquiry—describing what it is and what it is not—and by discussing what it is good for and why people do it. The remaining chapters build directly on the ideas presented in this chapter.

A first thing to know is that scientific inquiry is not all or nothing. “Scientificness” is a continuum. Inquiries can be more scientific or less scientific. What makes an inquiry more scientific? You might be surprised there is no universally agreed upon answer to this question. None of the descriptors we know of are sufficient by themselves to define scientific inquiry. But all of them give you a way of thinking about some aspects of the process of scientific inquiry. Each one gives you different insights.

An image of the book's description with the words like research, science, and inquiry and what the word research meant in the scientific world.

Exercise 1.2

As you read about each descriptor below, think about what would make an inquiry more or less scientific. If you think a descriptor is important, use it to revise your definition of scientific inquiry.

Creating an Image of Scientific Inquiry

We will present three descriptors of scientific inquiry. Each provides a different perspective and emphasizes a different aspect of scientific inquiry. We will draw on all three descriptors to compose our definition of scientific inquiry.

Descriptor 1. Experience Carefully Planned in Advance

Sir Ronald Fisher, often called the father of modern statistical design, once referred to research as “experience carefully planned in advance” (1935, p. 8). He said that humans are always learning from experience, from interacting with the world around them. Usually, this learning is haphazard rather than the result of a deliberate process carried out over an extended period of time. Research, Fisher said, was learning from experience, but experience carefully planned in advance.

This phrase can be fully appreciated by looking at each word. The fact that scientific inquiry is based on experience means that it is based on interacting with the world. These interactions could be thought of as the stuff of scientific inquiry. In addition, it is not just any experience that counts. The experience must be carefully planned . The interactions with the world must be conducted with an explicit, describable purpose, and steps must be taken to make the intended learning as likely as possible. This planning is an integral part of scientific inquiry; it is not just a preparation phase. It is one of the things that distinguishes scientific inquiry from many everyday learning experiences. Finally, these steps must be taken beforehand and the purpose of the inquiry must be articulated in advance of the experience. Clearly, scientific inquiry does not happen by accident, by just stumbling into something. Stumbling into something unexpected and interesting can happen while engaged in scientific inquiry, but learning does not depend on it and serendipity does not make the inquiry scientific.

Descriptor 2. Observing Something and Trying to Explain Why It Is the Way It Is

When we were writing this chapter and googled “scientific inquiry,” the first entry was: “Scientific inquiry refers to the diverse ways in which scientists study the natural world and propose explanations based on the evidence derived from their work.” The emphasis is on studying, or observing, and then explaining . This descriptor takes the image of scientific inquiry beyond carefully planned experience and includes explaining what was experienced.

According to the Merriam-Webster dictionary, “explain” means “(a) to make known, (b) to make plain or understandable, (c) to give the reason or cause of, and (d) to show the logical development or relations of” (Merriam-Webster, n.d. ). We will use all these definitions. Taken together, they suggest that to explain an observation means to understand it by finding reasons (or causes) for why it is as it is. In this sense of scientific inquiry, the following are synonyms: explaining why, understanding why, and reasoning about causes and effects. Our image of scientific inquiry now includes planning, observing, and explaining why.

An image represents the observation required in the scientific inquiry including planning and explaining.

We need to add a final note about this descriptor. We have phrased it in a way that suggests “observing something” means you are observing something in real time—observing the way things are or the way things are changing. This is often true. But, observing could mean observing data that already have been collected, maybe by someone else making the original observations (e.g., secondary analysis of NAEP data or analysis of existing video recordings of classroom instruction). We will address secondary analyses more fully in Chap. 4 . For now, what is important is that the process requires explaining why the data look like they do.

We must note that for us, the term “data” is not limited to numerical or quantitative data such as test scores. Data can also take many nonquantitative forms, including written survey responses, interview transcripts, journal entries, video recordings of students, teachers, and classrooms, text messages, and so forth.

An image represents the data explanation as it is not limited and takes numerous non-quantitative forms including an interview, journal entries, etc.

Exercise 1.3

What are the implications of the statement that just “observing” is not enough to count as scientific inquiry? Does this mean that a detailed description of a phenomenon is not scientific inquiry?

Find sources that define research in education that differ with our position, that say description alone, without explanation, counts as scientific research. Identify the precise points where the opinions differ. What are the best arguments for each of the positions? Which do you prefer? Why?

Descriptor 3. Updating Everyone’s Thinking in Response to More and Better Information

This descriptor focuses on a third aspect of scientific inquiry: updating and advancing the field’s understanding of phenomena that are investigated. This descriptor foregrounds a powerful characteristic of scientific inquiry: the reliability (or trustworthiness) of what is learned and the ultimate inevitability of this learning to advance human understanding of phenomena. Humans might choose not to learn from scientific inquiry, but history suggests that scientific inquiry always has the potential to advance understanding and that, eventually, humans take advantage of these new understandings.

Before exploring these bold claims a bit further, note that this descriptor uses “information” in the same way the previous two descriptors used “experience” and “observations.” These are the stuff of scientific inquiry and we will use them often, sometimes interchangeably. Frequently, we will use the term “data” to stand for all these terms.

An overriding goal of scientific inquiry is for everyone to learn from what one scientist does. Much of this book is about the methods you need to use so others have faith in what you report and can learn the same things you learned. This aspect of scientific inquiry has many implications.

One implication is that scientific inquiry is not a private practice. It is a public practice available for others to see and learn from. Notice how different this is from everyday learning. When you happen to learn something from your everyday experience, often only you gain from the experience. The fact that research is a public practice means it is also a social one. It is best conducted by interacting with others along the way: soliciting feedback at each phase, taking opportunities to present work-in-progress, and benefitting from the advice of others.

A second implication is that you, as the researcher, must be committed to sharing what you are doing and what you are learning in an open and transparent way. This allows all phases of your work to be scrutinized and critiqued. This is what gives your work credibility. The reliability or trustworthiness of your findings depends on your colleagues recognizing that you have used all appropriate methods to maximize the chances that your claims are justified by the data.

A third implication of viewing scientific inquiry as a collective enterprise is the reverse of the second—you must be committed to receiving comments from others. You must treat your colleagues as fair and honest critics even though it might sometimes feel otherwise. You must appreciate their job, which is to remain skeptical while scrutinizing what you have done in considerable detail. To provide the best help to you, they must remain skeptical about your conclusions (when, for example, the data are difficult for them to interpret) until you offer a convincing logical argument based on the information you share. A rather harsh but good-to-remember statement of the role of your friendly critics was voiced by Karl Popper, a well-known twentieth century philosopher of science: “. . . if you are interested in the problem which I tried to solve by my tentative assertion, you may help me by criticizing it as severely as you can” (Popper, 1968, p. 27).

A final implication of this third descriptor is that, as someone engaged in scientific inquiry, you have no choice but to update your thinking when the data support a different conclusion. This applies to your own data as well as to those of others. When data clearly point to a specific claim, even one that is quite different than you expected, you must reconsider your position. If the outcome is replicated multiple times, you need to adjust your thinking accordingly. Scientific inquiry does not let you pick and choose which data to believe; it mandates that everyone update their thinking when the data warrant an update.

Doing Scientific Inquiry

We define scientific inquiry in an operational sense—what does it mean to do scientific inquiry? What kind of process would satisfy all three descriptors: carefully planning an experience in advance; observing and trying to explain what you see; and, contributing to updating everyone’s thinking about an important phenomenon?

We define scientific inquiry as formulating , testing , and revising hypotheses about phenomena of interest.

Of course, we are not the only ones who define it in this way. The definition for the scientific method posted by the editors of Britannica is: “a researcher develops a hypothesis, tests it through various means, and then modifies the hypothesis on the basis of the outcome of the tests and experiments” (Britannica, n.d. ).

An image represents the scientific inquiry definition given by the editors of Britannica and also defines the hypothesis on the basis of the experiments.

Notice how defining scientific inquiry this way satisfies each of the descriptors. “Carefully planning an experience in advance” is exactly what happens when formulating a hypothesis about a phenomenon of interest and thinking about how to test it. “ Observing a phenomenon” occurs when testing a hypothesis, and “ explaining ” what is found is required when revising a hypothesis based on the data. Finally, “updating everyone’s thinking” comes from comparing publicly the original with the revised hypothesis.

Doing scientific inquiry, as we have defined it, underscores the value of accumulating knowledge rather than generating random bits of knowledge. Formulating, testing, and revising hypotheses is an ongoing process, with each revised hypothesis begging for another test, whether by the same researcher or by new researchers. The editors of Britannica signaled this cyclic process by adding the following phrase to their definition of the scientific method: “The modified hypothesis is then retested, further modified, and tested again.” Scientific inquiry creates a process that encourages each study to build on the studies that have gone before. Through collective engagement in this process of building study on top of study, the scientific community works together to update its thinking.

Before exploring more fully the meaning of “formulating, testing, and revising hypotheses,” we need to acknowledge that this is not the only way researchers define research. Some researchers prefer a less formal definition, one that includes more serendipity, less planning, less explanation. You might have come across more open definitions such as “research is finding out about something.” We prefer the tighter hypothesis formulation, testing, and revision definition because we believe it provides a single, coherent map for conducting research that addresses many of the thorny problems educational researchers encounter. We believe it is the most useful orientation toward research and the most helpful to learn as a beginning researcher.

A final clarification of our definition is that it applies equally to qualitative and quantitative research. This is a familiar distinction in education that has generated much discussion. You might think our definition favors quantitative methods over qualitative methods because the language of hypothesis formulation and testing is often associated with quantitative methods. In fact, we do not favor one method over another. In Chap. 4 , we will illustrate how our definition fits research using a range of quantitative and qualitative methods.

Exercise 1.4

Look for ways to extend what the field knows in an area that has already received attention by other researchers. Specifically, you can search for a program of research carried out by more experienced researchers that has some revised hypotheses that remain untested. Identify a revised hypothesis that you might like to test.

Unpacking the Terms Formulating, Testing, and Revising Hypotheses

To get a full sense of the definition of scientific inquiry we will use throughout this book, it is helpful to spend a little time with each of the key terms.

We first want to make clear that we use the term “hypothesis” as it is defined in most dictionaries and as it used in many scientific fields rather than as it is usually defined in educational statistics courses. By “hypothesis,” we do not mean a null hypothesis that is accepted or rejected by statistical analysis. Rather, we use “hypothesis” in the sense conveyed by the following definitions: “An idea or explanation for something that is based on known facts but has not yet been proved” (Cambridge University Press, n.d. ), and “An unproved theory, proposition, or supposition, tentatively accepted to explain certain facts and to provide a basis for further investigation or argument” (Agnes & Guralnik, 2008 ).

We distinguish two parts to “hypotheses.” Hypotheses consist of predictions and rationales . Predictions are statements about what you expect to find when you inquire about something. Rationales are explanations for why you made the predictions you did, why you believe your predictions are correct. So, for us “formulating hypotheses” means making explicit predictions and developing rationales for the predictions.

“Testing hypotheses” means making observations that allow you to assess in what ways your predictions were correct and in what ways they were incorrect. In education research, it is rarely useful to think of your predictions as either right or wrong. Because of the complexity of most issues you will investigate, most predictions will be right in some ways and wrong in others.

By studying the observations you make (data you collect) to test your hypotheses, you can revise your hypotheses to better align with the observations. This means revising your predictions plus revising your rationales to justify your adjusted predictions. Even though you might not run another test, formulating revised hypotheses is an essential part of conducting a research study. Comparing your original and revised hypotheses informs everyone of what you learned by conducting your study. In addition, a revised hypothesis sets the stage for you or someone else to extend your study and accumulate more knowledge of the phenomenon.

We should note that not everyone makes a clear distinction between predictions and rationales as two aspects of hypotheses. In fact, common, non-scientific uses of the word “hypothesis” may limit it to only a prediction or only an explanation (or rationale). We choose to explicitly include both prediction and rationale in our definition of hypothesis, not because we assert this should be the universal definition, but because we want to foreground the importance of both parts acting in concert. Using “hypothesis” to represent both prediction and rationale could hide the two aspects, but we make them explicit because they provide different kinds of information. It is usually easier to make predictions than develop rationales because predictions can be guesses, hunches, or gut feelings about which you have little confidence. Developing a compelling rationale requires careful thought plus reading what other researchers have found plus talking with your colleagues. Often, while you are developing your rationale you will find good reasons to change your predictions. Developing good rationales is the engine that drives scientific inquiry. Rationales are essentially descriptions of how much you know about the phenomenon you are studying. Throughout this guide, we will elaborate on how developing good rationales drives scientific inquiry. For now, we simply note that it can sharpen your predictions and help you to interpret your data as you test your hypotheses.

An image represents the rationale and the prediction for the scientific inquiry and different types of information provided by the terms.

Hypotheses in education research take a variety of forms or types. This is because there are a variety of phenomena that can be investigated. Investigating educational phenomena is sometimes best done using qualitative methods, sometimes using quantitative methods, and most often using mixed methods (e.g., Hay, 2016 ; Weis et al. 2019a ; Weisner, 2005 ). This means that, given our definition, hypotheses are equally applicable to qualitative and quantitative investigations.

Hypotheses take different forms when they are used to investigate different kinds of phenomena. Two very different activities in education could be labeled conducting experiments and descriptions. In an experiment, a hypothesis makes a prediction about anticipated changes, say the changes that occur when a treatment or intervention is applied. You might investigate how students’ thinking changes during a particular kind of instruction.

A second type of hypothesis, relevant for descriptive research, makes a prediction about what you will find when you investigate and describe the nature of a situation. The goal is to understand a situation as it exists rather than to understand a change from one situation to another. In this case, your prediction is what you expect to observe. Your rationale is the set of reasons for making this prediction; it is your current explanation for why the situation will look like it does.

You will probably read, if you have not already, that some researchers say you do not need a prediction to conduct a descriptive study. We will discuss this point of view in Chap. 2 . For now, we simply claim that scientific inquiry, as we have defined it, applies to all kinds of research studies. Descriptive studies, like others, not only benefit from formulating, testing, and revising hypotheses, but also need hypothesis formulating, testing, and revising.

One reason we define research as formulating, testing, and revising hypotheses is that if you think of research in this way you are less likely to go wrong. It is a useful guide for the entire process, as we will describe in detail in the chapters ahead. For example, as you build the rationale for your predictions, you are constructing the theoretical framework for your study (Chap. 3 ). As you work out the methods you will use to test your hypothesis, every decision you make will be based on asking, “Will this help me formulate or test or revise my hypothesis?” (Chap. 4 ). As you interpret the results of testing your predictions, you will compare them to what you predicted and examine the differences, focusing on how you must revise your hypotheses (Chap. 5 ). By anchoring the process to formulating, testing, and revising hypotheses, you will make smart decisions that yield a coherent and well-designed study.

Exercise 1.5

Compare the concept of formulating, testing, and revising hypotheses with the descriptions of scientific inquiry contained in Scientific Research in Education (NRC, 2002 ). How are they similar or different?

Exercise 1.6

Provide an example to illustrate and emphasize the differences between everyday learning/thinking and scientific inquiry.

Learning from Doing Scientific Inquiry

We noted earlier that a measure of what you have learned by conducting a research study is found in the differences between your original hypothesis and your revised hypothesis based on the data you collected to test your hypothesis. We will elaborate this statement in later chapters, but we preview our argument here.

Even before collecting data, scientific inquiry requires cycles of making a prediction, developing a rationale, refining your predictions, reading and studying more to strengthen your rationale, refining your predictions again, and so forth. And, even if you have run through several such cycles, you still will likely find that when you test your prediction you will be partly right and partly wrong. The results will support some parts of your predictions but not others, or the results will “kind of” support your predictions. A critical part of scientific inquiry is making sense of your results by interpreting them against your predictions. Carefully describing what aspects of your data supported your predictions, what aspects did not, and what data fell outside of any predictions is not an easy task, but you cannot learn from your study without doing this analysis.

An image represents the cycle of events that take place before making predictions, developing the rationale, and studying the prediction and rationale multiple times.

Analyzing the matches and mismatches between your predictions and your data allows you to formulate different rationales that would have accounted for more of the data. The best revised rationale is the one that accounts for the most data. Once you have revised your rationales, you can think about the predictions they best justify or explain. It is by comparing your original rationales to your new rationales that you can sort out what you learned from your study.

Suppose your study was an experiment. Maybe you were investigating the effects of a new instructional intervention on students’ learning. Your original rationale was your explanation for why the intervention would change the learning outcomes in a particular way. Your revised rationale explained why the changes that you observed occurred like they did and why your revised predictions are better. Maybe your original rationale focused on the potential of the activities if they were implemented in ideal ways and your revised rationale included the factors that are likely to affect how teachers implement them. By comparing the before and after rationales, you are describing what you learned—what you can explain now that you could not before. Another way of saying this is that you are describing how much more you understand now than before you conducted your study.

Revised predictions based on carefully planned and collected data usually exhibit some of the following features compared with the originals: more precision, more completeness, and broader scope. Revised rationales have more explanatory power and become more complete, more aligned with the new predictions, sharper, and overall more convincing.

Part II. Why Do Educators Do Research?

Doing scientific inquiry is a lot of work. Each phase of the process takes time, and you will often cycle back to improve earlier phases as you engage in later phases. Because of the significant effort required, you should make sure your study is worth it. So, from the beginning, you should think about the purpose of your study. Why do you want to do it? And, because research is a social practice, you should also think about whether the results of your study are likely to be important and significant to the education community.

If you are doing research in the way we have described—as scientific inquiry—then one purpose of your study is to understand , not just to describe or evaluate or report. As we noted earlier, when you formulate hypotheses, you are developing rationales that explain why things might be like they are. In our view, trying to understand and explain is what separates research from other kinds of activities, like evaluating or describing.

One reason understanding is so important is that it allows researchers to see how or why something works like it does. When you see how something works, you are better able to predict how it might work in other contexts, under other conditions. And, because conditions, or contextual factors, matter a lot in education, gaining insights into applying your findings to other contexts increases the contributions of your work and its importance to the broader education community.

Consequently, the purposes of research studies in education often include the more specific aim of identifying and understanding the conditions under which the phenomena being studied work like the observations suggest. A classic example of this kind of study in mathematics education was reported by William Brownell and Harold Moser in 1949 . They were trying to establish which method of subtracting whole numbers could be taught most effectively—the regrouping method or the equal additions method. However, they realized that effectiveness might depend on the conditions under which the methods were taught—“meaningfully” versus “mechanically.” So, they designed a study that crossed the two instructional approaches with the two different methods (regrouping and equal additions). Among other results, they found that these conditions did matter. The regrouping method was more effective under the meaningful condition than the mechanical condition, but the same was not true for the equal additions algorithm.

What do education researchers want to understand? In our view, the ultimate goal of education is to offer all students the best possible learning opportunities. So, we believe the ultimate purpose of scientific inquiry in education is to develop understanding that supports the improvement of learning opportunities for all students. We say “ultimate” because there are lots of issues that must be understood to improve learning opportunities for all students. Hypotheses about many aspects of education are connected, ultimately, to students’ learning. For example, formulating and testing a hypothesis that preservice teachers need to engage in particular kinds of activities in their coursework in order to teach particular topics well is, ultimately, connected to improving students’ learning opportunities. So is hypothesizing that school districts often devote relatively few resources to instructional leadership training or hypothesizing that positioning mathematics as a tool students can use to combat social injustice can help students see the relevance of mathematics to their lives.

We do not exclude the importance of research on educational issues more removed from improving students’ learning opportunities, but we do think the argument for their importance will be more difficult to make. If there is no way to imagine a connection between your hypothesis and improving learning opportunities for students, even a distant connection, we recommend you reconsider whether it is an important hypothesis within the education community.

Notice that we said the ultimate goal of education is to offer all students the best possible learning opportunities. For too long, educators have been satisfied with a goal of offering rich learning opportunities for lots of students, sometimes even for just the majority of students, but not necessarily for all students. Evaluations of success often are based on outcomes that show high averages. In other words, if many students have learned something, or even a smaller number have learned a lot, educators may have been satisfied. The problem is that there is usually a pattern in the groups of students who receive lower quality opportunities—students of color and students who live in poor areas, urban and rural. This is not acceptable. Consequently, we emphasize the premise that the purpose of education research is to offer rich learning opportunities to all students.

One way to make sure you will be able to convince others of the importance of your study is to consider investigating some aspect of teachers’ shared instructional problems. Historically, researchers in education have set their own research agendas, regardless of the problems teachers are facing in schools. It is increasingly recognized that teachers have had trouble applying to their own classrooms what researchers find. To address this problem, a researcher could partner with a teacher—better yet, a small group of teachers—and talk with them about instructional problems they all share. These discussions can create a rich pool of problems researchers can consider. If researchers pursued one of these problems (preferably alongside teachers), the connection to improving learning opportunities for all students could be direct and immediate. “Grounding a research question in instructional problems that are experienced across multiple teachers’ classrooms helps to ensure that the answer to the question will be of sufficient scope to be relevant and significant beyond the local context” (Cai et al., 2019b , p. 115).

As a beginning researcher, determining the relevance and importance of a research problem is especially challenging. We recommend talking with advisors, other experienced researchers, and peers to test the educational importance of possible research problems and topics of study. You will also learn much more about the issue of research importance when you read Chap. 5 .

Exercise 1.7

Identify a problem in education that is closely connected to improving learning opportunities and a problem that has a less close connection. For each problem, write a brief argument (like a logical sequence of if-then statements) that connects the problem to all students’ learning opportunities.

Part III. Conducting Research as a Practice of Failing Productively

Scientific inquiry involves formulating hypotheses about phenomena that are not fully understood—by you or anyone else. Even if you are able to inform your hypotheses with lots of knowledge that has already been accumulated, you are likely to find that your prediction is not entirely accurate. This is normal. Remember, scientific inquiry is a process of constantly updating your thinking. More and better information means revising your thinking, again, and again, and again. Because you never fully understand a complicated phenomenon and your hypotheses never produce completely accurate predictions, it is easy to believe you are somehow failing.

The trick is to fail upward, to fail to predict accurately in ways that inform your next hypothesis so you can make a better prediction. Some of the best-known researchers in education have been open and honest about the many times their predictions were wrong and, based on the results of their studies and those of others, they continuously updated their thinking and changed their hypotheses.

A striking example of publicly revising (actually reversing) hypotheses due to incorrect predictions is found in the work of Lee J. Cronbach, one of the most distinguished educational psychologists of the twentieth century. In 1955, Cronbach delivered his presidential address to the American Psychological Association. Titling it “Two Disciplines of Scientific Psychology,” Cronbach proposed a rapprochement between two research approaches—correlational studies that focused on individual differences and experimental studies that focused on instructional treatments controlling for individual differences. (We will examine different research approaches in Chap. 4 ). If these approaches could be brought together, reasoned Cronbach ( 1957 ), researchers could find interactions between individual characteristics and treatments (aptitude-treatment interactions or ATIs), fitting the best treatments to different individuals.

In 1975, after years of research by many researchers looking for ATIs, Cronbach acknowledged the evidence for simple, useful ATIs had not been found. Even when trying to find interactions between a few variables that could provide instructional guidance, the analysis, said Cronbach, creates “a hall of mirrors that extends to infinity, tormenting even the boldest investigators and defeating even ambitious designs” (Cronbach, 1975 , p. 119).

As he was reflecting back on his work, Cronbach ( 1986 ) recommended moving away from documenting instructional effects through statistical inference (an approach he had championed for much of his career) and toward approaches that probe the reasons for these effects, approaches that provide a “full account of events in a time, place, and context” (Cronbach, 1986 , p. 104). This is a remarkable change in hypotheses, a change based on data and made fully transparent. Cronbach understood the value of failing productively.

Closer to home, in a less dramatic example, one of us began a line of scientific inquiry into how to prepare elementary preservice teachers to teach early algebra. Teaching early algebra meant engaging elementary students in early forms of algebraic reasoning. Such reasoning should help them transition from arithmetic to algebra. To begin this line of inquiry, a set of activities for preservice teachers were developed. Even though the activities were based on well-supported hypotheses, they largely failed to engage preservice teachers as predicted because of unanticipated challenges the preservice teachers faced. To capitalize on this failure, follow-up studies were conducted, first to better understand elementary preservice teachers’ challenges with preparing to teach early algebra, and then to better support preservice teachers in navigating these challenges. In this example, the initial failure was a necessary step in the researchers’ scientific inquiry and furthered the researchers’ understanding of this issue.

We present another example of failing productively in Chap. 2 . That example emerges from recounting the history of a well-known research program in mathematics education.

Making mistakes is an inherent part of doing scientific research. Conducting a study is rarely a smooth path from beginning to end. We recommend that you keep the following things in mind as you begin a career of conducting research in education.

First, do not get discouraged when you make mistakes; do not fall into the trap of feeling like you are not capable of doing research because you make too many errors.

Second, learn from your mistakes. Do not ignore your mistakes or treat them as errors that you simply need to forget and move past. Mistakes are rich sites for learning—in research just as in other fields of study.

Third, by reflecting on your mistakes, you can learn to make better mistakes, mistakes that inform you about a productive next step. You will not be able to eliminate your mistakes, but you can set a goal of making better and better mistakes.

Exercise 1.8

How does scientific inquiry differ from everyday learning in giving you the tools to fail upward? You may find helpful perspectives on this question in other resources on science and scientific inquiry (e.g., Failure: Why Science is So Successful by Firestein, 2015).

Exercise 1.9

Use what you have learned in this chapter to write a new definition of scientific inquiry. Compare this definition with the one you wrote before reading this chapter. If you are reading this book as part of a course, compare your definition with your colleagues’ definitions. Develop a consensus definition with everyone in the course.

Part IV. Preview of Chap. 2

Now that you have a good idea of what research is, at least of what we believe research is, the next step is to think about how to actually begin doing research. This means how to begin formulating, testing, and revising hypotheses. As for all phases of scientific inquiry, there are lots of things to think about. Because it is critical to start well, we devote Chap. 2 to getting started with formulating hypotheses.

Agnes, M., & Guralnik, D. B. (Eds.). (2008). Hypothesis. In Webster’s new world college dictionary (4th ed.). Wiley.

Google Scholar

Britannica. (n.d.). Scientific method. In Encyclopaedia Britannica . Retrieved July 15, 2022 from https://www.britannica.com/science/scientific-method

Brownell, W. A., & Moser, H. E. (1949). Meaningful vs. mechanical learning: A study in grade III subtraction . Duke University Press..

Cai, J., Morris, A., Hohensee, C., Hwang, S., Robison, V., Cirillo, M., Kramer, S. L., & Hiebert, J. (2019b). Posing significant research questions. Journal for Research in Mathematics Education, 50 (2), 114–120. https://doi.org/10.5951/jresematheduc.50.2.0114

Article Google Scholar

Cambridge University Press. (n.d.). Hypothesis. In Cambridge dictionary . Retrieved July 15, 2022 from https://dictionary.cambridge.org/us/dictionary/english/hypothesis

Cronbach, J. L. (1957). The two disciplines of scientific psychology. American Psychologist, 12 , 671–684.

Cronbach, L. J. (1975). Beyond the two disciplines of scientific psychology. American Psychologist, 30 , 116–127.

Cronbach, L. J. (1986). Social inquiry by and for earthlings. In D. W. Fiske & R. A. Shweder (Eds.), Metatheory in social science: Pluralisms and subjectivities (pp. 83–107). University of Chicago Press.

Hay, C. M. (Ed.). (2016). Methods that matter: Integrating mixed methods for more effective social science research . University of Chicago Press.

Merriam-Webster. (n.d.). Explain. In Merriam-Webster.com dictionary . Retrieved July 15, 2022, from https://www.merriam-webster.com/dictionary/explain

National Research Council. (2002). Scientific research in education . National Academy Press.

Weis, L., Eisenhart, M., Duncan, G. J., Albro, E., Bueschel, A. C., Cobb, P., Eccles, J., Mendenhall, R., Moss, P., Penuel, W., Ream, R. K., Rumbaut, R. G., Sloane, F., Weisner, T. S., & Wilson, J. (2019a). Mixed methods for studies that address broad and enduring issues in education research. Teachers College Record, 121 , 100307.

Weisner, T. S. (Ed.). (2005). Discovering successful pathways in children’s development: Mixed methods in the study of childhood and family life . University of Chicago Press.

Download references

Author information

Authors and affiliations.

School of Education, University of Delaware, Newark, DE, USA

James Hiebert, Anne K Morris & Charles Hohensee

Department of Mathematical Sciences, University of Delaware, Newark, DE, USA

Jinfa Cai & Stephen Hwang

You can also search for this author in PubMed Google Scholar

Rights and permissions

Open Access This chapter is licensed under the terms of the Creative Commons Attribution 4.0 International License ( http://creativecommons.org/licenses/by/4.0/ ), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license and indicate if changes were made.

The images or other third party material in this chapter are included in the chapter's Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the chapter's Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder.

Reprints and permissions

Copyright information

About this chapter

Hiebert, J., Cai, J., Hwang, S., Morris, A.K., Hohensee, C. (2023). What Is Research, and Why Do People Do It?. In: Doing Research: A New Researcher’s Guide. Research in Mathematics Education. Springer, Cham. https://doi.org/10.1007/978-3-031-19078-0_1

Download citation

DOI : https://doi.org/10.1007/978-3-031-19078-0_1

Published : 03 December 2022

Publisher Name : Springer, Cham

Print ISBN : 978-3-031-19077-3

Online ISBN : 978-3-031-19078-0

eBook Packages : Education Education (R0)

Share this chapter

Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

Publish with us

Policies and ethics

Find a journal
Track your research

Astrological Guide to Choosing the Perfect Perfume
Importance Of Paraphrasing In Academic Writing And Research
5 Ways Paraphrasing Is Important In Academic Writing With Examples
Importance of Unlocking the Potential of Free Satellite Imagery: Types, Uses, Sources
Importance of Ejari in Dubai

8 Reasons Why Research is Important and Steps to Conduct Research

Research is a vital component of today’s society and significantly impacts our lives. It is impossible to exaggerate the importance of research since it gives us important knowledge and insights into various facets of life.

Research greatly influences our daily lives, from understanding diseases and discovering treatments to creating new technologies and inventions. However, this article will discuss eight factors that make research important and how it affects society.

So, why is research important? Let’s get into the article to discover the answer to your question.

Table of Contents

Importance of Research

There are several reasons why research is important. In every aspect of our lives, research plays a vital role. These aspects may include:

Making informed decisions,
Advancing technology and innovation,
Resolving real-world issues,
Enhancing education and learning,
Promoting economic growth, and
Ensuring that facts support laws and policies.

Moreover, researchers can find new knowledge that advances our understanding of a particular topic by performing in-depth examinations and experiments. We may use this information to address problems in the real world and apply it to various sectors, including social sciences and medicine.

We can make wiser decisions regarding our health, finances, and other matters because of the accurate and dependable knowledge we receive through research.

Why Research Matters: Uncovering the Top 8 Reasons

This section will cover the top reasons for the importance of research. Let’s get in to explore!

1. Acquire Knowledge Effectively

Research is a good method of learning about a certain subject. Researchers conduct lengthy studies and experiments to get insightful findings and collect and analyze data. By providing us deeper understanding and knowledge about the topic, this process helps us make better judgments.

Whether you are a professional, a student, or just someone interested, research is a great way to learn new things and expand your knowledge.

2. Helps in Problem-Solving

Real-world problem-solving heavily relies on research. Researchers perform studies and experiments to determine the underlying causes of a certain problem and create methods to solve it.

For example, social science research has assisted in addressing challenges like poverty, injustice, and prejudice, while medical research has contributed to discovering vaccinations and life-saving therapies.

Research aids us in addressing some of the most difficult issues our society is now experiencing by offering answers supported by evidence.

3. Provides the Latest Information

Research gives us the most recent and accurate information about a given subject. Researchers revise their studies to account for changes when new revelations and data are discovered.

This guarantees that we consistently use the most up-to-date and trustworthy information, enabling us to make better and more informed decisions. In order to succeed, you need to have access to the most recent knowledge, regardless of your line of work, whether it is business, school, or anything else.

4. Builds Credibility

Building credibility in your profession via research is beneficial. You show your knowledge and competence on a subject when you undertake research and publish your results.

This might offer new professional growth and development prospects by establishing you as an authority in your sector. Furthermore, you demonstrate your dedication to accuracy and dependability by relying on evidence-based information, further boosting your credibility .

5. Helps in Business Success

Businesses must conduct research if they want to succeed. Companies may find new possibilities, comprehend customer preferences, and create development plans by performing market research .

Research also aids in spotting emerging trends and technology that might provide companies with a competitive edge. Research enables businesses to remain ahead of the curve and achieve long-term success by investing.

6. Discover and Seize Opportunities

Want to get benefits from new opportunities? Say yes to research.

Finding and taking advantage of new opportunities is made easier by research. Research may assist you in spotting new trends and potential development areas, whether you are an entrepreneur, a student, or a professional.

Keeping up with the most recent research will enable you to spot fresh chances for professional and personal growth, which will help you realize your objectives.

7. Introduces You to New Ideas

Another reason for the importance of research is it introduces you to various new ideas. You learn new concepts and methods of thinking through research.

You can discover multiple theories, thoughts, and problem-solving methods by reading research papers and publications. This can deepen your comprehension of a topic and present fresh professional and personal development opportunities.

Let’s say you are an Instagram influencer and want new content ideas. By thoroughly researching new trends and problems people face nowadays, you will get multiple ideas for your content.

8. Helps You to Reach People

Research makes reaching people and understanding their thoughts, attitudes, and behaviors possible. Researchers can gather data and use it to analyze it to acquire insights into the beliefs and attitudes of various groups of people by researching a certain issue.

This information helps in understanding how and why individuals make decisions. Additionally, research can be used to identify consumer needs and preferences, allowing businesses to create targeted marketing campaigns.

Overall, research is a wonderful tool for interacting with people since it allows us to understand them better and make decisions based on their thoughts and feedback.

How to Improve Your Research Skills

As research is vital in every field, it is also an important task to improve your research skills. In this section, we will discover all the tips and tricks for mastering and making the most out of your research skills .

1. Start with a Big Picture and Make Work Your Way Down

A clear idea of the larger picture is one of the most critical parts of conducting research. This entails having a wide awareness of the issue under consideration and the context in which it exists.

Beginning with the large picture and working your way down might assist you in identifying the essential concepts and ideas most important to your research issue. Consider the situation where you are researching the impact of social media on mental health. In such a scenario, you may begin by studying the origins and development of social media, as well as its various uses and negative effects.

You may then focus on certain platforms and their impact on mental health. However, you can find the most relevant sources of information and ensure your research is thorough and well-informed by having a clear awareness of the broader picture.

2. Identify Reliable Sources

Finding trustworthy sources of information is the next step after having a firm grasp of the larger picture. Peer-reviewed publications published by respected publishers and founded on reliable research methodologies are considered reliable.

There are several methods for locating reliable sources of information. One of the most effective approaches is utilizing academic databases like JSTOR, Google Scholar, and PubMed.

These databases enable you to look for publications that have undergone peer review and have been issued by respectable publishers. To find trustworthy information sources, you may also speak with subject-respective experts, librarians, and other experts in your industry.

3. Validate Information from Multiple Sources

The next step is to validate the data you acquired from multiple sources after identifying your information sources. To make sure the data you’ve obtained from various sources is reliable and consistent, you should compare and contrast it.

Searching for confirming evidence from several sources is one technique to verify the information. Similar findings from several sources increase the likelihood that the data is accurate.

To confirm that the writers of the sources you are utilizing are competent to write on the subject, you may also verify their qualifications and experience.

4. Take in New Information

Constantly absorbing fresh information is another important component of strengthening your research abilities. This entails staying up-to-date with the most recent findings and advancements inside and outside your profession.

Reading blogs, signing up for academic journals and newsletters, attending conferences, and taking seminars are all fantastic methods to keep up with the most recent developments and trends in your profession.

5. Stay Organized

Keeping organized is one of the most important aspects of conducting research. This entails recording the sources you have used, making notes, and putting your thoughts and ideas in a simple structure to find and comprehend.

By making it simple to save and manage sources, create citations and bibliographies, and make notes on the sources you have used, using a citation manager like Mendeley, EndNote, or Zotero may help you keep organized.

You can also organize your thoughts and ideas to access and comprehend them by generating an outline or mind map. This helps you in staying on course and ensuring that your research is thorough and organized.

Steps to Conduct Research for Beginners

For new researchers, doing research may be a difficult task. However, it can be a rewarding and enjoyable experience with the right approach and mindset.

Here are some steps that new researchers can take to conduct effective research:

1. Define Your Research Question

Defining your research question is the initial stage in every research project. It must be precise, understandable, and comprehensible. You may stay focused and be guided through the research process using a solid research question.

2. Conduct a Literature Review

It’s very important to perform a literature review before beginning your research. To do this, you must locate and read the relevant literature on the subject of your study. It can support your study and help you find gaps in existing knowledge and possible research avenues.

3. Choose Your Research Methodology

There are various research methodologies you can use in your research. These may include:

Interviews,
Experiments, and
Case studies.

Selecting the technique that best suits your research topic is important to guarantee that you gather the data you need to answer your research question.

4. Collect and Analyze Data

Data collection may begin once your research topic has been established, a literature review has been completed, and your methodology has been decided upon. This includes gathering and recording data from various sources, including surveys, interviews, and experiments.

After gathering data, you must analyze it to conclude your research topic. Depending on the data you have gathered, you may need to employ statistical analysis, coding, or other procedures.

5. Interpret Your Results

Following data analysis, it’s critical to interpret your findings. This entails interpreting the information and coming to conclusions that address your research issue. When interpreting your results, it’s crucial to be unbiased and objective.

6. Communicate Your Findings

Sharing your results is the last stage. This entails succinctly and clearly articulating your study topic, technique, data gathering, analysis, and interpretation. To display your findings, you can utilize a variety of forms, including reports, presentations, and articles.

Although it requires patience, focus, and critical thinking, conducting research can be rewarding and interesting.

Why is Marketing Research Important?

Any company that wants to succeed in today’s competitive business environment must invest in marketing research. It entails compiling and evaluating data on customers, rivals, and the market at large.

This information is utilized to create efficient marketing plans, enhance goods and services, and make wise business decisions.

1. Better Business-Client Understanding

The ability to better understand clients is one of the main benefits of marketing research for firms. Businesses can discover patterns and trends that might guide their marketing strategy by gathering data on customer behavior, preferences, and attitudes.

For instance, if a company discovers that a substantial portion of its clients favors eco-friendly items, it may utilize this knowledge to create and promote goods that satisfy this need.

2. It Helps in Staying Competitive

By monitoring the tactics and products of rival companies, marketing research also helps organizations stay competitive. Businesses can find ways to set themselves apart and obtain a competitive edge by examining the strengths and shortcomings of their rivals.

3. It Helps in Identifying Potential Risks

Additionally, marketing research can assist companies in identifying and reducing potential risks. Businesses may foresee prospective market shifts and modify their plans appropriately by gathering data on market trends and customer behavior.

This can help them avoid expensive errors and adjust rapidly to evolving situations.

In conclusion, research is important in many facets of life, whether for personal or professional reasons. It is impossible to neglect the importance of research since it gives us the knowledge and information we need to solve issues, innovate, and make wise decisions.

By strengthening our research abilities, we can efficiently acquire and analyze data, maintain organization, and utilize priceless resources like libraries and specialists.

Moreover, research is useful in marketing because it helps companies understand their customers, assess the success of their marketing campaigns, and spot possible dangers. Research is an effective instrument that we may use to further our objectives and improve the world.

International Day for Abolition of Slavery

13 Reasons You Should Be Choosing Quality Over Quantity

You may also like, importance of imagination [12 reasons], importance of employee relation and how employee relation plan can be implemented in an organization, pin it on pinterest.

An official website of the United States government

The .gov means it’s official. Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

The site is secure. The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

Publications
Account settings

Preview improvements coming to the PMC website in October 2024. Learn More or Try it out now .

Advanced Search
Journal List
Arab J Urol
v.12(1); 2014 Mar

Why should I do research? Is it a waste of time?

Athanasios dellis.

a 2nd Department of Surgery, Aretaieion Hospital, University of Athens, Greece

Andreas Skolarikos

b 2nd Department of Urology, Sismanogleion Hospital, University of Athens, Greece

Athanasios G. Papatsoris

• In medicine, research is the search for scientific knowledge, which is crucial for the development of novel medications and techniques.
• Conducting research provides a deeper understanding of several scientific topics of the specialty of each doctor.
• Research through RCTs represents the principal methodological approach.
• There are two main research processes; qualitative and quantitative studies.
• It is important to develop Research Units in hospitals and medical centres.
• Ethics and the high quality of research are ensured by committees (i.e., Internal Board Review, Ethics Research Committee).
• Research sessions could be implemented in the job plans of doctors.
• Research is not a waste of time, but a scientific investment.

To answer the questions ‘Why should I do research? Is it a waste of time?’ and present relevant issues.

Medline was used to identify relevant articles published from 2000 to 2013, using the following keywords ‘medicine’, ‘research’, ‘purpose’, ‘study’, ‘trial’, ‘urology’.

Research is the most important activity to achieve scientific progress. Although it is an easy process on a theoretical basis, practically it is a laborious process, and full commitment and dedication are of paramount importance. Currently, given that the financial crisis has a key influence in daily practice, the need to stress the real purpose of research is crucial.

Research is necessary and not a waste of time. Efforts to improving medical knowledge should be continuous.

What is research?

Research is a general term that covers all processes aiming to find responses to worthwhile scientific questions by means of a systematic and scientific approach. In fact, research is the search for scientific knowledge, a systematically formal process to increase the fund of knowledge and use it properly for the development of novel applications.

There are several types of research, such as basic science laboratory research, translational research, and clinical and population-based research. Medical research through randomised clinical trials (RCTs) represents the principal methodological approach for the structured assessment of medical outcomes. RCTs provide prospective and investigator-controlled studies, representing the highest level of evidence (LoE) and grade of recommendation, and define the ultimate practice guideline [1] . However, many constraints, such as ethical, economic and/or social issues, render the conduct of RCTs difficult and their application problematic. For instance, in one of the largest RCTs in urology, on preventing prostate cancer with finasteride, the LoE was 1 [2] . In this RCT, after 7 years of finasteride chemoprevention, the rate of cancer decreased from 24.4% to 18.4%. Based on this study, it could be postulated that finasteride chemoprevention should be offered to men in the general population in an attempt to reduce the risk of prostate cancer. However, the findings of this RCT could not be implemented universally due to financial issues [3] .

There are two main research processes, i.e., qualitative and quantitative studies. Although very different in structure and methods, these studies represent two arms of the same research body. Qualitative studies are based mainly on human experience, using notions and theoretical information without quantifying variables, while quantitative studies record information obtained from participants in a numerical form, to enable a statistical analysis of the data. Therefore, quantitative studies can be used to establish the existence of associative or causal relationships between variables.

From a practical perspective, adding a Research Unit to a Medical Department would ultimately enhance clinical practice and education. As such, almost all hospitals in Western countries have research and development (R&D) departments, where the R&D can be linked with clinical innovation. Basic areas in this field include business planning, sales policies and activities, model design, and strategic propositions and campaign development. However, if researchers are not motivated, the research could be counterproductive, and the whole process could ultimately be a waste of time and effort [4] .

The ethics and the high quality of research are ensured by committees, such as the Internal Review Board, and Ethics Research Committees, especially in academic hospitals. They consist of highly educated and dedicated scientists of good faith as well as objectivity, to be the trustees of ethical and properly designed and performed studies.

Do we need research?

Research is the fuel for future progress and it has significantly shaped perspectives in medicine. In urology there are numerous examples showing that current practice has rapidly changed as a result of several key research findings. For example, from the research of Huggins and Hodges (who won the Nobel Prize in 1966), hormone therapy has become the standard treatment for patients with advanced/metastatic prostate cancer. The use of ESWL to treat stones in the urinary tract is another example of research that has improved practice in urology. The current trend in urology to use robotic assistance in surgery is a relatively recent example of how constant research worldwide improves everyday clinical practice [5] . Furthermore, in a more sophisticated field, research is used to identify factors influencing decision-making, clarify the preferred alternatives, and encourage the selection of a preferred screening option in diseases such as prostate cancer [6,7] .

Conducting research provides a deeper understanding of several scientific topics within the specialty of each doctor. Furthermore, it helps doctors of a particular specialty to understand better the scientific work of other colleagues. Despite the different areas of interest between the different specialties, there are common research methods.

In a University, PhD and MSc students concentrate their efforts at higher research levels. Apart from having to produce a challenging and stimulating thesis, young researchers try to develop their analytical, conceptual and critical thinking skills to the highest academic level. Also, postgraduate students thus prepare themselves for a future job in the global market.

During the research process several approaches can be tested and compared for their safety and efficacy, while the results of this procedure can be recorded and statistically analysed to extract the relevant results. Similarly, any aspects of false results and side-effects, e.g., for new medications, can be detected and properly evaluated to devise every possible improvement. Hence, research components under the auspices of dedicated supervisors, assisted by devoted personnel, are of utmost importance. Also, funding is a catalyst for the optimum progress of the research programme, and it must be independent from any other financial source with a possible conflict. Unfortunately, in cases of economic crisis in a hospital, the first department that is trimmed is research.

Is research time a waste of time?

Even if the right personnel are appointed and the funding is secured, it would be a great mistake to believe that the results are guaranteed. Full commitment and dedication are of utmost importance for successful research. Also, these questions are raised in relation to the scientific papers that are accepted for publication in medical journals. About US$ 160 billion is spent every year on biomedical research [8] . Recently, in the Lancet [9] it was estimated that 85% of research is wasteful or inefficient, with deficiencies presented in the following questions: (1) is the research question relevant for clinicians or patients?; (2) are the design and methods appropriate?; (3) is the full report accessible?; (4) is it unbiased and clinically meaningful? Such questions about the importance, purpose and impact of research should surely be answered during the research. The view of the general public is that the purpose of medical research is to advance knowledge for the good of society, to invent new substances to fight disease, to create diagnostic and therapeutic algorithms, to improve public health, to prevent diseases, to improve the quality of life and to prolong overall survival.

Pharmaceutical companies that sponsor research are financially orientated. This fact leads to a sole result, i.e., profit, as a return on their investment. In this framework it would be impossible for academic institutions to operate on any other basis but finance. Economic indicators, even better benefits and the commercial potential of research are important for their survival. Nevertheless, the purpose of research is more than that. It is time to reframe the way research is done and rewarded, leaving profits in second place. We need to remind ourselves about the real purpose of scientific research. Moreover, we need to decide what research is needed and what impact it is likely to have. Researchers and those who benefit from research (i.e., patients, practising doctors) have a crucial role in the research process. Academic institutions should assess and reward researchers on a long-term basis, and help them to concentrate on meaningful research. Researchers must defend their selection of topics as being those appropriate to benefit public health.

Each medical specialty has a different working plan, and surgical specialties such as urology are characterised by a lack of time for research. It is suggested that specific sessions for research could be implemented in the job plan of urologists, and for other doctors. This is more important for the ‘academic doctor’, but even non-academic doctors could undertake research, if only of the current updated medical literature.

Last but not least is the issue of teaching research to junior doctors. This is very important, as the sooner each doctor is involved in the research process the better for his or her career. Even for junior doctors who are not interested in an academic career, understanding the research process helps them to develop their scientific skills. Young doctors should be motivated to understand and undertake research. However, it is important to guide them through the basic principles of research and to mentor them during their first scientific projects. Furthermore, specific academic training opportunities should be offered within developing programmes, such as the academic specialist registrar’s career pathways in the UK [10] .

In conclusion, research is necessary and not a waste of time. All relevant components of the research engine should co-operate to achieve scientific progress that will help patients and the general population.

Take-home messages

• Ethics and the high quality of research are ensured by committees (i.e. Internal Board Review, Ethical Research Committee).

Conflict of interest

Source of funding.

Peer review under responsibility of Arab Association of Urology.

An external file that holds a picture, illustration, etc.
Object name is fx1.jpg

Home » Significance of the Study – Examples and Writing Guide

Significance of the Study – Examples and Writing Guide

Table of Contents

Significance of the Study

Definition:

Significance of the study in research refers to the potential importance, relevance, or impact of the research findings. It outlines how the research contributes to the existing body of knowledge, what gaps it fills, or what new understanding it brings to a particular field of study.

In general, the significance of a study can be assessed based on several factors, including:

Originality : The extent to which the study advances existing knowledge or introduces new ideas and perspectives.
Practical relevance: The potential implications of the study for real-world situations, such as improving policy or practice.
Theoretical contribution: The extent to which the study provides new insights or perspectives on theoretical concepts or frameworks.
Methodological rigor : The extent to which the study employs appropriate and robust methods and techniques to generate reliable and valid data.
Social or cultural impact : The potential impact of the study on society, culture, or public perception of a particular issue.

Types of Significance of the Study

The significance of the Study can be divided into the following types:

Theoretical Significance

Theoretical significance refers to the contribution that a study makes to the existing body of theories in a specific field. This could be by confirming, refuting, or adding nuance to a currently accepted theory, or by proposing an entirely new theory.

Practical Significance

Practical significance refers to the direct applicability and usefulness of the research findings in real-world contexts. Studies with practical significance often address real-life problems and offer potential solutions or strategies. For example, a study in the field of public health might identify a new intervention that significantly reduces the spread of a certain disease.

Significance for Future Research

This pertains to the potential of a study to inspire further research. A study might open up new areas of investigation, provide new research methodologies, or propose new hypotheses that need to be tested.

How to Write Significance of the Study

Here’s a guide to writing an effective “Significance of the Study” section in research paper, thesis, or dissertation:

Background : Begin by giving some context about your study. This could include a brief introduction to your subject area, the current state of research in the field, and the specific problem or question your study addresses.
Identify the Gap : Demonstrate that there’s a gap in the existing literature or knowledge that needs to be filled, which is where your study comes in. The gap could be a lack of research on a particular topic, differing results in existing studies, or a new problem that has arisen and hasn’t yet been studied.
State the Purpose of Your Study : Clearly state the main objective of your research. You may want to state the purpose as a solution to the problem or gap you’ve previously identified.
Contributes to the existing body of knowledge.
Addresses a significant research gap.
Offers a new or better solution to a problem.
Impacts policy or practice.
Leads to improvements in a particular field or sector.
Identify Beneficiaries : Identify who will benefit from your study. This could include other researchers, practitioners in your field, policy-makers, communities, businesses, or others. Explain how your findings could be used and by whom.
Future Implications : Discuss the implications of your study for future research. This could involve questions that are left open, new questions that have been raised, or potential future methodologies suggested by your study.

Significance of the Study in Research Paper

The Significance of the Study in a research paper refers to the importance or relevance of the research topic being investigated. It answers the question “Why is this research important?” and highlights the potential contributions and impacts of the study.

The significance of the study can be presented in the introduction or background section of a research paper. It typically includes the following components:

Importance of the research problem: This describes why the research problem is worth investigating and how it relates to existing knowledge and theories.
Potential benefits and implications: This explains the potential contributions and impacts of the research on theory, practice, policy, or society.
Originality and novelty: This highlights how the research adds new insights, approaches, or methods to the existing body of knowledge.
Scope and limitations: This outlines the boundaries and constraints of the research and clarifies what the study will and will not address.

Suppose a researcher is conducting a study on the “Effects of social media use on the mental health of adolescents”.

The significance of the study may be:

“The present study is significant because it addresses a pressing public health issue of the negative impact of social media use on adolescent mental health. Given the widespread use of social media among this age group, understanding the effects of social media on mental health is critical for developing effective prevention and intervention strategies. This study will contribute to the existing literature by examining the moderating factors that may affect the relationship between social media use and mental health outcomes. It will also shed light on the potential benefits and risks of social media use for adolescents and inform the development of evidence-based guidelines for promoting healthy social media use among this population. The limitations of this study include the use of self-reported measures and the cross-sectional design, which precludes causal inference.”

Significance of the Study In Thesis

The significance of the study in a thesis refers to the importance or relevance of the research topic and the potential impact of the study on the field of study or society as a whole. It explains why the research is worth doing and what contribution it will make to existing knowledge.

For example, the significance of a thesis on “Artificial Intelligence in Healthcare” could be:

With the increasing availability of healthcare data and the development of advanced machine learning algorithms, AI has the potential to revolutionize the healthcare industry by improving diagnosis, treatment, and patient outcomes. Therefore, this thesis can contribute to the understanding of how AI can be applied in healthcare and how it can benefit patients and healthcare providers.
AI in healthcare also raises ethical and social issues, such as privacy concerns, bias in algorithms, and the impact on healthcare jobs. By exploring these issues in the thesis, it can provide insights into the potential risks and benefits of AI in healthcare and inform policy decisions.
Finally, the thesis can also advance the field of computer science by developing new AI algorithms or techniques that can be applied to healthcare data, which can have broader applications in other industries or fields of research.

Significance of the Study in Research Proposal

The significance of a study in a research proposal refers to the importance or relevance of the research question, problem, or objective that the study aims to address. It explains why the research is valuable, relevant, and important to the academic or scientific community, policymakers, or society at large. A strong statement of significance can help to persuade the reviewers or funders of the research proposal that the study is worth funding and conducting.

Here is an example of a significance statement in a research proposal:

Title : The Effects of Gamification on Learning Programming: A Comparative Study

Significance Statement:

This proposed study aims to investigate the effects of gamification on learning programming. With the increasing demand for computer science professionals, programming has become a fundamental skill in the computer field. However, learning programming can be challenging, and students may struggle with motivation and engagement. Gamification has emerged as a promising approach to improve students’ engagement and motivation in learning, but its effects on programming education are not yet fully understood. This study is significant because it can provide valuable insights into the potential benefits of gamification in programming education and inform the development of effective teaching strategies to enhance students’ learning outcomes and interest in programming.

Examples of Significance of the Study

Here are some examples of the significance of a study that indicates how you can write this into your research paper according to your research topic:

Research on an Improved Water Filtration System : This study has the potential to impact millions of people living in water-scarce regions or those with limited access to clean water. A more efficient and affordable water filtration system can reduce water-borne diseases and improve the overall health of communities, enabling them to lead healthier, more productive lives.

Study on the Impact of Remote Work on Employee Productivity : Given the shift towards remote work due to recent events such as the COVID-19 pandemic, this study is of considerable significance. Findings could help organizations better structure their remote work policies and offer insights on how to maximize employee productivity, wellbeing, and job satisfaction.

Investigation into the Use of Solar Power in Developing Countries : With the world increasingly moving towards renewable energy, this study could provide important data on the feasibility and benefits of implementing solar power solutions in developing countries. This could potentially stimulate economic growth, reduce reliance on non-renewable resources, and contribute to global efforts to combat climate change.

Research on New Learning Strategies in Special Education : This study has the potential to greatly impact the field of special education. By understanding the effectiveness of new learning strategies, educators can improve their curriculum to provide better support for students with learning disabilities, fostering their academic growth and social development.

Examination of Mental Health Support in the Workplace : This study could highlight the impact of mental health initiatives on employee wellbeing and productivity. It could influence organizational policies across industries, promoting the implementation of mental health programs in the workplace, ultimately leading to healthier work environments.

Evaluation of a New Cancer Treatment Method : The significance of this study could be lifesaving. The research could lead to the development of more effective cancer treatments, increasing the survival rate and quality of life for patients worldwide.

When to Write Significance of the Study

The Significance of the Study section is an integral part of a research proposal or a thesis. This section is typically written after the introduction and the literature review. In the research process, the structure typically follows this order:

Title – The name of your research.
Abstract – A brief summary of the entire research.
Introduction – A presentation of the problem your research aims to solve.
Literature Review – A review of existing research on the topic to establish what is already known and where gaps exist.
Significance of the Study – An explanation of why the research matters and its potential impact.

In the Significance of the Study section, you will discuss why your study is important, who it benefits, and how it adds to existing knowledge or practice in your field. This section is your opportunity to convince readers, and potentially funders or supervisors, that your research is valuable and worth undertaking.

Advantages of Significance of the Study

The Significance of the Study section in a research paper has multiple advantages:

Establishes Relevance: This section helps to articulate the importance of your research to your field of study, as well as the wider society, by explicitly stating its relevance. This makes it easier for other researchers, funders, and policymakers to understand why your work is necessary and worth supporting.
Guides the Research: Writing the significance can help you refine your research questions and objectives. This happens as you critically think about why your research is important and how it contributes to your field.
Attracts Funding: If you are seeking funding or support for your research, having a well-written significance of the study section can be key. It helps to convince potential funders of the value of your work.
Opens up Further Research: By stating the significance of the study, you’re also indicating what further research could be carried out in the future, based on your work. This helps to pave the way for future studies and demonstrates that your research is a valuable addition to the field.
Provides Practical Applications: The significance of the study section often outlines how the research can be applied in real-world situations. This can be particularly important in applied sciences, where the practical implications of research are crucial.
Enhances Understanding: This section can help readers understand how your study fits into the broader context of your field, adding value to the existing literature and contributing new knowledge or insights.

Limitations of Significance of the Study

The Significance of the Study section plays an essential role in any research. However, it is not without potential limitations. Here are some that you should be aware of:

Subjectivity: The importance and implications of a study can be subjective and may vary from person to person. What one researcher considers significant might be seen as less critical by others. The assessment of significance often depends on personal judgement, biases, and perspectives.
Predictability of Impact: While you can outline the potential implications of your research in the Significance of the Study section, the actual impact can be unpredictable. Research doesn’t always yield the expected results or have the predicted impact on the field or society.
Difficulty in Measuring: The significance of a study is often qualitative and can be challenging to measure or quantify. You can explain how you think your research will contribute to your field or society, but measuring these outcomes can be complex.
Possibility of Overstatement: Researchers may feel pressured to amplify the potential significance of their study to attract funding or interest. This can lead to overstating the potential benefits or implications, which can harm the credibility of the study if these results are not achieved.
Overshadowing of Limitations: Sometimes, the significance of the study may overshadow the limitations of the research. It is important to balance the potential significance with a thorough discussion of the study’s limitations.
Dependence on Successful Implementation: The significance of the study relies on the successful implementation of the research. If the research process has flaws or unexpected issues arise, the anticipated significance might not be realized.

About the author

Muhammad Hassan

Researcher, Academic Writer, Web developer

Research Approach – Types Methods and Examples

Ethical Considerations – Types, Examples and...

Research Results Section – Writing Guide and...

Data Interpretation – Process, Methods and...

How to Publish a Research Paper – Step by Step...

Future Research – Thesis Guide

Board Members
Management Team
Become a Contributor
Volunteer Opportunities
Code of Ethical Practices

KNOWLEDGE NETWORK

Search Engines List
Suggested Reading Library
Web Directories
Research Papers
Industry News

Become a Member
Associate Membership
Certified Membership
Membership Application
Corporate Application

CIRS Certification Program
CIRS Certification Objectives
CIRS Certification Benefits
CIRS Certification Exam
Maintain Your Certification

Upcoming Events
Live Classes
Classes Schedule
Webinars Schedules

Latest Articles
Internet Research
Search Techniques
Research Methods
Business Research
Search Engines
Research & Tools
Investigative Research
Internet Search
Work from Home
Internet Ethics
Internet Privacy

Six Reasons Why Research is Important

Everyone conducts research in some form or another from a young age, whether news, books, or browsing the Internet. Internet users come across thoughts, ideas, or perspectives - the curiosity that drives the desire to explore. However, when research is essential to make practical decisions, the nature of the study alters - it all depends on its application and purpose. For instance, skilled research offered as a research paper service has a definite objective, and it is focused and organized. Professional research helps derive inferences and conclusions from solving problems. visit the HB tool services for the amazing research tools that will help to solve your problems regarding the research on any project.

What is the Importance of Research?

The primary goal of the research is to guide action, gather evidence for theories, and contribute to the growth of knowledge in data analysis. This article discusses the importance of research and the multiple reasons why it is beneficial to everyone, not just students and scientists.

On the other hand, research is important in business decision-making because it can assist in making better decisions when combined with their experience and intuition.

Reasons for the Importance of Research

Acquire Knowledge Effectively
Research helps in problem-solving
Provides the latest information
Builds credibility
Helps in business success
Discover and Seize opportunities

1- Acquire Knowledge Efficiently through Research

The most apparent reason to conduct research is to understand more. Even if you think you know everything there is to know about a subject, there is always more to learn. Research helps you expand on any prior knowledge you have of the subject. The research process creates new opportunities for learning and progress.

2- Research Helps in Problem-solving

Problem-solving can be divided into several components, which require knowledge and analysis, for example, identification of issues, cause identification, identifying potential solutions, decision to take action, monitoring and evaluation of activity and outcomes.

You may just require additional knowledge to formulate an informed strategy and make an informed decision. When you know you've gathered reliable data, you'll be a lot more confident in your answer.

3- Research Provides the Latest Information

Research enables you to seek out the most up-to-date facts. There is always new knowledge and discoveries in various sectors, particularly scientific ones. Staying updated keeps you from falling behind and providing inaccurate or incomplete information. You'll be better prepared to discuss a topic and build on ideas if you have the most up-to-date information. With the help of tools and certifications such as CIRS , you may learn internet research skills quickly and easily. Internet research can provide instant, global access to information.

4- Research Builds Credibility

Research provides a solid basis for formulating thoughts and views. You can speak confidently about something you know to be true. It's much more difficult for someone to find flaws in your arguments after you've finished your tasks. In your study, you should prioritize the most reputable sources. Your research should focus on the most reliable sources. You won't be credible if your "research" comprises non-experts' opinions. People are more inclined to pay attention if your research is excellent.

5- Research Helps in Business Success

R&D might also help you gain a competitive advantage. Finding ways to make things run more smoothly and differentiate a company's products from those of its competitors can help to increase a company's market worth.

6- Research Discover and Seize Opportunities

People can maximize their potential and achieve their goals through various opportunities provided by research. These include getting jobs, scholarships, educational subsidies, projects, commercial collaboration, and budgeted travel. Research is essential for anyone looking for work or a change of environment. Unemployed people will have a better chance of finding potential employers through job advertisements or agencies.

How to Improve Your Research Skills

Start with the big picture and work your way down.

It might be hard to figure out where to start when you start researching. There's nothing wrong with a simple internet search to get you started. Online resources like Google and Wikipedia are a great way to get a general idea of a subject, even though they aren't always correct. They usually give a basic overview with a short history and any important points.

Identify Reliable Source

Not every source is reliable, so it's critical that you can tell the difference between the good ones and the bad ones. To find a reliable source, use your analytical and critical thinking skills and ask yourself the following questions: Is this source consistent with other sources I've discovered? Is the author a subject matter expert? Is there a conflict of interest in the author's point of view on this topic?

Validate Information from Various Sources

Take in new information.

The purpose of research is to find answers to your questions, not back up what you already assume. Only looking for confirmation is a minimal way to research because it forces you to pick and choose what information you get and stops you from getting the most accurate picture of the subject. When you do research, keep an open mind to learn as much as possible.

Facilitates Learning Process

Learning new things and implementing them in daily life can be frustrating. Finding relevant and credible information requires specialized training and web search skills due to the sheer enormity of the Internet and the rapid growth of indexed web pages. On the other hand, short courses and Certifications like CIRS make the research process more accessible. CIRS Certification offers complete knowledge from beginner to expert level. You can become a Certified Professional Researcher and get a high-paying job, but you'll also be much more efficient and skilled at filtering out reliable data. You can learn more about becoming a Certified Professional Researcher.

Stay Organized

You'll see a lot of different material during the process of gathering data, from web pages to PDFs to videos. You must keep all of this information organized in some way so that you don't lose anything or forget to mention something properly. There are many ways to keep your research project organized, but here are a few of the most common: Learning Management Software , Bookmarks in your browser, index cards, and a bibliography that you can add to as you go are all excellent tools for writing.

Make Use of the library's Resources

If you still have questions about researching, don't worry—even if you're not a student performing academic or course-related research, there are many resources available to assist you. Many high school and university libraries, in reality, provide resources not only for staff and students but also for the general public. Look for research guidelines or access to specific databases on the library's website. Association of Internet Research Specialists enjoys sharing informational content such as research-related articles , research papers , specialized search engines list compiled from various sources, and contributions from our members and in-house experts.

of Conducting Research

Latest from erin r. goodrich.

Strategies for Job Hunting in the Digital Age for 2024
Enhancing Efficiency: The Role of Technology in Personal Injury Case Management
The Evolution and Future of Workplace Benefit Administration

Live Classes Schedule

OCT 15 CIRS Certification Internet Research Training Program Live Classes Online

World's leading professional association of Internet Research Specialists - We deliver Knowledge, Education, Training, and Certification in the field of Professional Online Research. The AOFIRS is considered a major contributor in improving Web Search Skills and recognizes Online Research work as a full-time occupation for those that use the Internet as their primary source of information.

Get Exclusive Research Tips in Your Inbox

Privacy Policy
Terms & Conditions
Advertising Opportunities
Knowledge Network

More From Forbes

The role of research at universities: why it matters.

Share to Facebook
Share to Twitter
Share to Linkedin

(Photo by William B. Plowman/Getty Images)

Teaching and learning, research and discovery, synthesis and creativity, understanding and engagement, service and outreach. There are many “core elements” to the mission of a great university. Teaching would seem the most obvious, but for those outside of the university, “research” (taken to include scientific research, scholarship more broadly, as well as creative activity) may be the least well understood. This creates misunderstanding of how universities invest resources, especially those deriving from undergraduate tuition and state (or other public) support, and the misperception that those resources are being diverted away from what is believed should be the core (and sole) focus, teaching. This has led to a loss of trust, confidence, and willingness to continue to invest or otherwise support (especially our public) universities.

Why are universities engaged in the conduct of research? Who pays? Who benefits? And why does it all matter? Good questions. Let’s get to some straightforward answers. Because the academic research enterprise really is not that difficult to explain, and its impacts are profound.

So let’s demystify university-based research. And in doing so, hopefully we can begin building both better understanding and a better relationship between the public and higher education, both of which are essential to the future of US higher education.

Why are universities engaged in the conduct of research?

Universities engage in research as part of their missions around learning and discovery. This, in turn, contributes directly and indirectly to their primary mission of teaching. Universities and many colleges (the exception being those dedicated exclusively to undergraduate teaching) have as part of their mission the pursuit of scholarship. This can come in the form of fundamental or applied research (both are most common in the STEM fields, broadly defined), research-based scholarship or what often is called “scholarly activity” (most common in the social sciences and humanities), or creative activity (most common in the arts). Increasingly, these simple categorizations are being blurred, for all good reasons and to the good of the discovery of new knowledge and greater understanding of complex (transdisciplinary) challenges and the creation of increasingly interrelated fields needed to address them.

It goes without saying that the advancement of knowledge (discovery, innovation, creation) is essential to any civilization. Our nation’s research universities represent some of the most concentrated communities of scholars, facilities, and collective expertise engaged in these activities. But more importantly, this is where higher education is delivered, where students develop breadth and depth of knowledge in foundational and advanced subjects, where the skills for knowledge acquisition and understanding (including contextualization, interpretation, and inference) are honed, and where students are educated, trained, and otherwise prepared for successful careers. Part of that training and preparation derives from exposure to faculty who are engaged at the leading-edge of their fields, through their research and scholarly work. The best faculty, the teacher-scholars, seamlessly weave their teaching and research efforts together, to their mutual benefit, and in a way that excites and engages their students. In this way, the next generation of scholars (academic or otherwise) is trained, research and discovery continue to advance inter-generationally, and the cycle is perpetuated.

Best High-Yield Savings Accounts Of 2024

Best 5% interest savings accounts of 2024.

University research can be expensive, particularly in laboratory-intensive fields. But the responsibility for much (indeed most) of the cost of conducting research falls to the faculty member. Faculty who are engaged in research write grants for funding (e.g., from federal and state agencies, foundations, and private companies) to support their work and the work of their students and staff. In some cases, the universities do need to invest heavily in equipment, facilities, and personnel to support select research activities. But they do so judiciously, with an eye toward both their mission, their strategic priorities, and their available resources.

Medical research, and medical education more broadly, is expensive and often requires substantial institutional investment beyond what can be covered by clinical operations or externally funded research. But universities with medical schools/medical centers have determined that the value to their educational and training missions as well as to their communities justifies the investment. And most would agree that university-based medical centers are of significant value to their communities, often providing best-in-class treatment and care in midsize and smaller communities at a level more often seen in larger metropolitan areas.

Research in the STEM fields (broadly defined) can also be expensive. Scientific (including medical) and engineering research often involves specialized facilities or pieces of equipment, advanced computing capabilities, materials requiring controlled handling and storage, and so forth. But much of this work is funded, in large part, by federal agencies such as the National Science Foundation, National Institutes of Health, US Department of Energy, US Department of Agriculture, and many others.

Research in the social sciences is often (not always) less expensive, requiring smaller amount of grant funding. As mentioned previously, however, it is now becoming common to have physical, natural, and social scientist teams pursuing large grant funding. This is an exciting and very promising trend for many reasons, not the least of which is the nature of the complex problems being studied.

Research in the arts and humanities typically requires the least amount of funding as it rarely requires the expensive items listed previously. Funding from such organizations as the National Endowment for the Arts, National Endowment for the Humanities, and private foundations may be able to support significant scholarship and creation of new knowledge or works through much more modest grants than would be required in the natural or physical sciences, for example.

Philanthropy may also be directed toward the support of research and scholarly activity at universities. Support from individual donors, family foundations, private or corporate foundations may be directed to support students, faculty, labs or other facilities, research programs, galleries, centers, and institutes.

Who benefits?

Students, both undergraduate and graduate, benefit from studying in an environment rich with research and discovery. Besides what the faculty can bring back to the classroom, there are opportunities to engage with faculty as part of their research teams and even conduct independent research under their supervision, often for credit. There are opportunities to learn about and learn on state-of-the-art equipment, in state-of-the-art laboratories, and from those working on the leading edge in a discipline. There are opportunities to co-author, present at conferences, make important connections, and explore post-graduate pathways.

The broader university benefits from active research programs. Research on timely and important topics attracts attention, which in turn leads to greater institutional visibility and reputation. As a university becomes known for its research in certain fields, they become magnets for students, faculty, grants, media coverage, and even philanthropy. Strength in research helps to define a university’s “brand” in the national and international marketplace, impacting everything from student recruitment, to faculty retention, to attracting new investments.

The community, region, and state benefits from the research activity of the university. This is especially true for public research universities. Research also contributes directly to economic development, clinical, commercial, and business opportunities. Resources brought into the university through grants and contracts support faculty, staff, and student salaries, often adding additional jobs, contributing directly to the tax base. Research universities, through their expertise, reputation, and facilities, can attract new businesses into their communities or states. They can also launch and incubate startup companies, or license and sell their technologies to other companies. Research universities often host meeting and conferences which creates revenue for local hotels, restaurants, event centers, and more. And as mentioned previously, university medical centers provide high-quality medical care, often in midsize communities that wouldn’t otherwise have such outstanding services and state-of-the-art facilities.

(Photo by Justin Sullivan/Getty Images)

And finally, why does this all matter?

Research is essential to advancing society, strengthening the economy, driving innovation, and addressing the vexing and challenging problems we face as a people, place, and planet. It’s through research, scholarship, and discovery that we learn about our history and ourselves, understand the present context in which we live, and plan for and secure our future.

Research universities are vibrant, exciting, and inspiring places to learn and to work. They offer opportunities for students that few other institutions can match – whether small liberal arts colleges, mid-size teaching universities, or community colleges – and while not right for every learner or every educator, they are right for many, if not most. The advantages simply cannot be ignored. Neither can the importance or the need for these institutions. They need not be for everyone, and everyone need not find their way to study or work at our research universities, and we stipulate that there are many outstanding options to meet and support different learning styles and provide different environments for teaching and learning. But it’s critically important that we continue to support, protect, and respect research universities for all they do for their students, their communities and states, our standing in the global scientific community, our economy, and our nation.

Editorial Standards
Reprints & Permissions

Join The Conversation

One Community. Many Voices. Create a free account to share your thoughts.

Forbes Community Guidelines

Our community is about connecting people through open and thoughtful conversations. We want our readers to share their views and exchange ideas and facts in a safe space.

In order to do so, please follow the posting rules in our site's Terms of Service. We've summarized some of those key rules below. Simply put, keep it civil.

Your post will be rejected if we notice that it seems to contain:

False or intentionally out-of-context or misleading information
Insults, profanity, incoherent, obscene or inflammatory language or threats of any kind
Attacks on the identity of other commenters or the article's author
Content that otherwise violates our site's terms.

User accounts will be blocked if we notice or believe that users are engaged in:

Continuous attempts to re-post comments that have been previously moderated/rejected
Racist, sexist, homophobic or other discriminatory comments
Attempts or tactics that put the site security at risk
Actions that otherwise violate our site's terms.

So, how can you be a power user?

Stay on topic and share your insights
Feel free to be clear and thoughtful to get your point across
‘Like’ or ‘Dislike’ to show your point of view.
Protect your community.
Use the report tool to alert us when someone breaks the rules.

Thanks for reading our community guidelines. Please read the full list of posting rules found in our site's Terms of Service.

What is Research Ethics?

Originally published 1999-2013 at Resources for Research Ethics Education, a web project directed by Michael Kalichman, Ph.D., and Dena Plemmons, Ph.D., from the University of California-San Diego Research Ethics Program and the San Diego Research Ethics Consortium. Republished with permission.

See Also: Teaching Research Ethics: Why Teach?

Research Ethics is defined here to be the ethics of the planning, conduct, and reporting of research.

It is clear that research ethics should include:

Protections of human and animal subjects

However, not all researchers use human or animal subjects, nor are the ethical dimensions of research confined solely to protections for research subjects. Other ethical challenges are rooted in many dimensions of research, including the:

Collection, use, and interpretation of research data
Methods for reporting and reviewing research plans or findings
Relationships among researchers with one another
Relationships between researchers and those that will be affected by their research
Means for responding to misunderstandings, disputes, or misconduct
Options for promoting ethical conduct in research

For the purpose of this online resource, the domain of research ethics is intended to include nothing less than the fostering of research that protects the interests of the public, the subjects of research, and the researchers themselves.

Important Ethical Distinctions

In discussing or teaching research ethics, it is important to keep some basic distinctions in mind.

Prescriptive vs. descriptive claims

It is important not to confuse moral claims about how people ought to behave with descriptive claims about how they in fact do behave. From the fact that gift authorship or signing off on unreviewed data may be “common practice” in some contexts, it doesn’t follow that they are morally or professionally justified. Nor is morality to be confused with the moral beliefs or ethical codes that a given group or society holds (how some group thinks people should live). A belief in segregation is not morally justified simply because it is widely held by a group of people or given society. Philosophers term this distinction between prescriptive and descriptive claims the “is-ought distinction.”

Law vs. morality

A second important distinction is that between morality and the law. The law may or may not conform to the demands of ethics (Kagan, 1998). To take a contemporary example: many believe that the law prohibiting federally funded stem cell research is objectionable on moral (as well as scientific) grounds, i.e., that such research can save lives and prevent much human misery. History is full of examples of bad laws, that is laws now regarded as morally unjustifiable, e.g., the laws of apartheid, laws prohibiting women from voting or inter-racial couples from marrying.

It is also helpful to distinguish between two different levels of discussion (or two different kinds of ethical questions): first-order or “ground-level” questions and second-order questions.

First-order questions

First-order moral questions concern what we should do. Such questions may be very general or quite specific. One might ask whether the tradition of “senior” authorship should be defended and preserved or, more generally, what are the principles that should go into deciding the issue of senior authorship. Such questions and the substantive proposals regarding how to answer them belong to the domain of what moral philosophers call “normative ethics.”

Second-order questions

Second-order moral questions concern the nature and purpose of morality itself. When someone claims that falsifying data is wrong, what exactly is the standing of this claim? What exactly does the word “wrong” mean in the conduct of scientific research? And what are we doing when we make claims about right and wrong, scientific integrity and research misconduct? These second-order questions are quite different from the ground-level questions about how to conduct one’s private or professional life raised above. They concern the nature of morality rather than its content, i.e., what acts are required, permitted or prohibited. This is the domain of what moral philosophers call “metaethics” (Kagan, 1998).

Ways to Approach Ethics

Each of these approaches provides moral principles and ways of thinking about the responsibilities, duties and obligations of moral life. Individually and jointly, they can provide practical guidance in ethical decision-making.

Deontological ethics

One of the most influential and familiar approaches to ethics is deontological ethics, associated with Immanuel Kant (1742-1804). Deontological ethics hold certain acts as right or wrong in themselves, e.g., promise breaking or lying. So, for example, in the context of research, fraud, plagiarism and misrepresentation are regarded as morally wrong in themselves, not simply because they (tend to) have bad consequences. The deontological approach is generally grounded in a single fundamental principle: Act as you would wish others to act towards you OR always treat persons as an end, never as a means to an end.

From such central principles are derived rules or guidelines for what is permitted, required and prohibited. Objections to principle-based or deontological ethics include the difficulty of applying highly general principles to specific cases, e.g.: Does treating persons as ends rule out physician-assisted suicide, or require it? Deontological ethics is generally contrasted to consequentialist ethics (Honderich, 1995).

Consequentialist ethics

According to consequentialist approaches, the rightness or wrongness of an action depends solely on its consequences. One should act in such a way as to bring about the best state of affairs, where the best state of affairs may be understood in various ways, e.g., as the greatest happiness for the greatest number of people, maximizing pleasure and minimizing pain or maximizing the satisfaction of preferences. A theory such as Utilitarianism (with its roots in the work of Jeremy Bentham and John Stuart Mill) is generally taken as the paradigm example of consequentialism. Objections to consequentialist ethics tend to focus on its willingness to regard individual rights and values as “negotiable.” So, for example, most people would regard murder as wrong independently of the fact that killing one person might allow several others to be saved (the infamous sacrifice of an ailing patient to provide organs for several other needy patients). Similarly, widespread moral opinion holds certain values important (integrity, justice) not only because they generally lead to good outcomes, but in and of themselves.

Virtue ethics

Virtue ethics focuses on moral character rather than action and behavior considered in isolation. Central to this approach is the question what ought we (as individuals, as scientists, as physicians) to be rather than simply what we ought to do. The emphasis here is on inner states, that is, moral dispositions and habits such as courage or a developed sense of personal integrity. Virtue ethics can be a useful approach in the context of RCR and professional ethics, emphasizing the importance of moral virtues such as compassion, honesty, and respect. This approach has also a great deal to offer in discussions of bioethical issues where a traditional emphasis on rights and abstract principles frequently results in polarized, stalled discussions (e.g., abortion debates contrasting the rights of the mother against the rights of the fetus).

An ethics of care

The term “ethics of care” grows out of the work of Carol Gilligan, whose empirical work in moral psychology claimed to discover a “different voice,” a mode of moral thinking distinct from principle-based moral thinking (e.g., the theories of Kant and Mill). An ethics of care stresses compassion and empathetic understanding, virtues Gilligan associated with traditional care-giving roles, especially those of women.

This approach differs from traditional moral theories in two important ways. First, it assumes that it is the connections between persons, e.g., lab teams, colleagues, parents and children, student and mentor, not merely the rights and obligations of discrete individuals that matter. The moral world, on this view, is best seen not as the interaction of discrete individuals, each with his or her own interests and rights, but as an interrelated web of obligations and commitment. We interact, much of the time, not as private individuals, but as members of families, couples, institutions, research groups, a given profession and so on. Second, these human relationships, including relationships of dependency, play a crucial role on this account in determining what our moral obligations and responsibilities are. So, for example, individuals have special responsibilities to care for their children, students, patients, and research subjects.

An ethics of care is thus particularly useful in discussing human and animal subjects research, issues of informed consent, and the treatment of vulnerable populations such as children, the infirm or the ill.

Casuistry or case study approaches

The case study approach begins from real or hypothetical cases. Its objective is to identify the intuitively plausible principles that should be taken into account in resolving the issues at hand. The case study approach then proceeds to critically evaluate those principles. In discussing whistle-blowing, for example, a good starting point is with recent cases of research misconduct, seeking to identify and evaluate principles such as a commitment to the integrity of science, protecting privacy, or avoiding false or unsubstantiated charges. In the context of RCR instruction, case studies provide one of the most interesting and effective approaches to developing sensitivity to ethical issues and to honing ethical decision-making skills.

Strictly speaking, casuistry is more properly understood as a method for doing ethics rather than as itself an ethical theory. However, casuistry is not wholly unconnected to ethical theory. The need for a basis upon which to evaluate competing principles, e.g., the importance of the well-being of an individual patient vs. a concern for just allocation of scarce medical resources, makes ethical theory relevant even with case study approaches.

Applied ethics

Applied ethics is a branch of normative ethics. It deals with practical questions particularly in relation to the professions. Perhaps the best known area of applied ethics is bioethics, which deals with ethical questions arising in medicine and the biological sciences, e.g., questions concerning the application of new areas of technology (stem cells, cloning, genetic screening, nanotechnology, etc.), end of life issues, organ transplants, and just distribution of healthcare. Training in responsible conduct of research or “research ethics” is merely one among various forms of professional ethics that have come to prominence since the 1960s. Worth noting, however, is that concern with professional ethics is not new, as ancient codes such as the Hippocratic Oath and guild standards attest (Singer, 1986).

Research Ethics

Adams, D., Pimple, K.D. (2005). Research Misconduct and Crime: Lessons from Criminal Science on Preventing Misconduct and Promoting Integrity. Accountability in Research, 12 (3): 225-240.
Anderson, M.S., Horn, A.S., Risbey, K.R., Ronning, E.A., De Vries, R., Martinson, B.C. (2007). What Do Mentoring and Training in the Responsible Conduct of Research Have To Do with Scientists’ Misbehavior? Findings from a National Survey of NIH-Funded Scientists. Academic Medicine, 82 (9): 853-860.
Bulger, R.E. & Heitman, E. (2007). Expanding Responsible Conduct of Research Instruction across the University. Academic Medicine, 82 (9): 876-878.
Kalichman, M.W. (2006). Ethics and Science: A 0.1% solution. Issues in Science and Technology, 23 : 34-36.
Kalichman, M.W. (2007). Responding to Challenges in Educating for the Responsible Conduct of Research. Academic Medicine, 82 (9): 870-875.
Kalichman, M.W., Plemmons, D.K. (2007). Reported Goals for Responsible Conduct of Research Courses. Academic Medicine, 82 (9): 846-852.
Kalichman, M.W. (2009). Evidence-based research ethics. The American Journal of Bioethics, 9 (6&7): 85-87.
Pimple, K.D. (2002). Six Domains of Research Ethics: A Heuristic Framework for the Responsible Conduct of Research. Science and Engineering Ethics, 8 (2): 191-205.
Steneck, N.H. (2006). Fostering Integrity in Research: Definitions, Current Knowledge, and Future Directions. Science and Engineering Ethics, 12 : 53-74.
Steneck, N.H., Bulger, R.E. (2007). The History, Purpose, and Future of Instruction in the Responsible Conduct of Research. Academic Medicine, 82 (9): 829-834.
Vasgird, D.R. (2007). Prevention over Cure: The Administrative Rationale for Education in the Responsible Conduct of Research. Academic Medicine, 82 (9): 835-837.
Aristotle. The Nichomachean Ethics .
Beauchamp, R.L. & Childress, J.F. (2001). Principles of Biomedical Ethics , 5th edition. NY: Oxford University Press.
Bentham, J. (1781). An Introduction to the Principles of Morals and Legislation.
Gilligan, C. (1993). In a Different Voice: Psychological Theory and Women’s Development. Cambridge: Harvard University Press.
Glover, Jonathan. (1977). Causing Death and Saving Lives. Penguin Books.
Honderich, T, ed. (1995). The Oxford Companion to Philosophy. Oxford and New York: Oxford University Press.
Kagan, S. (1998). Normative Ethics . Westview Press.
Kant, I. (1785). Groundwork of the Metaphysics of Morals .
Kant, I. (1788). Critique of Practical Reason .
Kant, I. (1797). The Metaphysics of Morals .
Kant, I. (1797). On a Supposed right to Lie from Benevolent Motives .
Kuhse, H. & Singer, P. (1999). Bioethics: An Anthology . Blackwell Publishers.
Mill, J.S. (1861). Utilitarianism.
Rachels, J. (1999). The Elements of Moral Philosophy , 3rd edition. Boston: McGraw-Hill.
Regan, T. (1993). Matters of Life and Death: New Introductory Essays in Moral Philosophy , 3rd edition. New York: McGraw-Hill. The history of ethics
Singer, P (1993). Practical Ethics , 2nd ed. Cambridge University Press

2. Psychological Research

Why is research important, learning objectives.

By the end of this section, you will be able to:

Explain how scientific research addresses questions about behavior
Discuss how scientific research guides public policy
Appreciate how scientific research can be important in making personal decisions

Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people’s authority, and blind luck. While many of us feel confident in our abilities to decipher and interact with the world around us, history is filled with examples of how very wrong we can be when we fail to recognize the need for evidence in supporting claims. At various times in history, we would have been certain that the sun revolved around a flat earth, that the earth’s continents did not move, and that mental illness was caused by possession ( [link] ). It is through systematic scientific research that we divest ourselves of our preconceived notions and superstitions and gain an objective understanding of ourselves and our world.

Some of our ancestors, across the world and over the centuries, believed that trephination—the practice of making a hole in the skull, as shown here—allowed evil spirits to leave the body, thus curing mental illness and other disorders. (credit: “taiproject”/Flickr)

USE OF RESEARCH INFORMATION

Trying to determine which theories are and are not accepted by the scientific community can be difficult, especially in an area of research as broad as psychology. More than ever before, we have an incredible amount of information at our fingertips, and a simple internet search on any given research topic might result in a number of contradictory studies. In these cases, we are witnessing the scientific community going through the process of reaching a consensus, and it could be quite some time before a consensus emerges. For example, the hypothesized link between exposure to media violence and subsequent aggression has been debated in the scientific community for roughly 60 years. Even today, we will find detractors, but a consensus is building. Several professional organizations view media violence exposure as a risk factor for actual violence, including the American Medical Association, the American Psychiatric Association, and the American Psychological Association (American Academy of Pediatrics, American Academy of Child & Adolescent Psychiatry, American Psychological Association, American Medical Association, American Academy of Family Physicians, American Psychiatric Association, 2000).

In the meantime, we should strive to think critically about the information we encounter by exercising a degree of healthy skepticism. When someone makes a claim, we should examine the claim from a number of different perspectives: what is the expertise of the person making the claim, what might they gain if the claim is valid, does the claim seem justified given the evidence, and what do other researchers think of the claim? This is especially important when we consider how much information in advertising campaigns and on the internet claims to be based on “scientific evidence” when in actuality it is a belief or perspective of just a few individuals trying to sell a product or draw attention to their perspectives.

We should be informed consumers of the information made available to us because decisions based on this information have significant consequences. One such consequence can be seen in politics and public policy. Imagine that you have been elected as the governor of your state. One of your responsibilities is to manage the state budget and determine how to best spend your constituents’ tax dollars. As the new governor, you need to decide whether to continue funding the D.A.R.E. (Drug Abuse Resistance Education) program in public schools ( [link] ). This program typically involves police officers coming into the classroom to educate students about the dangers of becoming involved with alcohol and other drugs. According to the D.A.R.E. website (www.dare.org), this program has been very popular since its inception in 1983, and it is currently operating in 75% of school districts in the United States and in more than 40 countries worldwide. Sounds like an easy decision, right? However, on closer review, you discover that the vast majority of research into this program consistently suggests that participation has little, if any, effect on whether or not someone uses alcohol or other drugs (Clayton, Cattarello, & Johnstone, 1996; Ennett, Tobler, Ringwalt, & Flewelling, 1994; Lynam et al., 1999; Ringwalt, Ennett, & Holt, 1991). If you are committed to being a good steward of taxpayer money, will you fund this particular program, or will you try to find other programs that research has consistently demonstrated to be effective?

The D.A.R.E. program continues to be popular in schools around the world despite research suggesting that it is ineffective.

Link to Learning

Watch this news report to learn more about some of the controversial issues surrounding the D.A.R.E. program.

Ultimately, it is not just politicians who can benefit from using research in guiding their decisions. We all might look to research from time to time when making decisions in our lives. Imagine you just found out that a close friend has breast cancer or that one of your young relatives has recently been diagnosed with autism. In either case, you want to know which treatment options are most successful with the fewest side effects. How would you find that out? You would probably talk with your doctor and personally review the research that has been done on various treatment options—always with a critical eye to ensure that you are as informed as possible.

THE PROCESS OF SCIENTIFIC RESEARCH

Scientific knowledge is advanced through a process known as the scientific method . Basically, ideas (in the form of theories and hypotheses) are tested against the real world (in the form of empirical observations), and those empirical observations lead to more ideas that are tested against the real world, and so on. In this sense, the scientific process is circular. The types of reasoning within the circle are called deductive and inductive. In deductive reasoning , ideas are tested against the empirical world; in inductive reasoning , empirical observations lead to new ideas ( [link] ). These processes are inseparable, like inhaling and exhaling, but different research approaches place different emphasis on the deductive and inductive aspects.

Psychological research relies on both inductive and deductive reasoning.

In the scientific context, deductive reasoning begins with a generalization—one hypothesis—that is then used to reach logical conclusions about the real world. If the hypothesis is correct, then the logical conclusions reached through deductive reasoning should also be correct. A deductive reasoning argument might go something like this: All living things require energy to survive (this would be your hypothesis). Ducks are living things. Therefore, ducks require energy to survive (logical conclusion). In this example, the hypothesis is correct; therefore, the conclusion is correct as well. Sometimes, however, an incorrect hypothesis may lead to a logical but incorrect conclusion. Consider this argument: all ducks are born with the ability to see. Quackers is a duck. Therefore, Quackers was born with the ability to see. Scientists use deductive reasoning to empirically test their hypotheses. Returning to the example of the ducks, researchers might design a study to test the hypothesis that if all living things require energy to survive, then ducks will be found to require energy to survive.

Deductive reasoning starts with a generalization that is tested against real-world observations; however, inductive reasoning moves in the opposite direction. Inductive reasoning uses empirical observations to construct broad generalizations. Unlike deductive reasoning, conclusions drawn from inductive reasoning may or may not be correct, regardless of the observations on which they are based. For instance, you may notice that your favorite fruits—apples, bananas, and oranges—all grow on trees; therefore, you assume that all fruit must grow on trees. This would be an example of inductive reasoning, and, clearly, the existence of strawberries, blueberries, and kiwi demonstrate that this generalization is not correct despite it being based on a number of direct observations. Scientists use inductive reasoning to formulate theories, which in turn generate hypotheses that are tested with deductive reasoning. In the end, science involves both deductive and inductive processes.

Play this “Deal Me In” interactive card game to practice using inductive reasoning.

We’ve stated that theories and hypotheses are ideas, but what sort of ideas are they, exactly? A theory is a well-developed set of ideas that propose an explanation for observed phenomena. Theories are repeatedly checked against the world, but they tend to be too complex to be tested all at once; instead, researchers create hypotheses to test specific aspects of a theory.

The scientific method of research includes proposing hypotheses, conducting research, and creating or modifying theories based on results.

A scientific hypothesis is also falsifiable , or capable of being shown to be incorrect. Recall from the introductory chapter that Sigmund Freud had lots of interesting ideas to explain various human behaviors ( [link] ). However, a major criticism of Freud’s theories is that many of his ideas are not falsifiable; for example, it is impossible to imagine empirical observations that would disprove the existence of the id, the ego, and the superego—the three elements of personality described in Freud’s theories. Despite this, Freud’s theories are widely taught in introductory psychology texts because of their historical significance for personality psychology and psychotherapy, and these remain the root of all modern forms of therapy.

Many of the specifics of (a) Freud’s theories, such as (b) his division of the mind into id, ego, and superego, have fallen out of favor in recent decades because they are not falsifiable. In broader strokes, his views set the stage for much of psychological thinking today, such as the unconscious nature of the majority of psychological processes.

Visit this website to apply the scientific method and practice its steps by using them to solve a murder mystery, determine why a student is in trouble, and design an experiment to test house paint.

Scientists are engaged in explaining and understanding how the world around them works, and they are able to do so by coming up with theories that generate hypotheses that are testable and falsifiable. Theories that stand up to their tests are retained and refined, while those that do not are discarded or modified. In this way, research enables scientists to separate fact from simple opinion. Having good information generated from research aids in making wise decisions both in public policy and in our personal lives.

Self Check Questions

Critical thinking questions.

2. The scientific method is often described as self-correcting and cyclical. Briefly describe your understanding of the scientific method with regard to these concepts.

Personal Application Questions

3. Healthcare professionals cite an enormous number of health problems related to obesity, and many people have an understandable desire to attain a healthy weight. There are many diet programs, services, and products on the market to aid those who wish to lose weight. If a close friend was considering purchasing or participating in one of these products, programs, or services, how would you make sure your friend was fully aware of the potential consequences of this decision? What sort of information would you want to review before making such an investment or lifestyle change yourself?

1. There is probably tremendous political pressure to appear to be hard on drugs. Therefore, even though D.A.R.E. might be ineffective, it is a well-known program with which voters are familiar.

Psychology. Authored by : OpenStax College. Located at : http://cnx.org/contents/[email protected]:1/Psychology . License : CC BY: Attribution . License Terms : Download for free at http://cnx.org/content/col11629/latest/.

What Does Good Research Look Like? Three Hallmarks Of Successful Customer Research

Senem Guler Biyikli , Analyst

Having conversations with clients and learning from their experiences is one of the best parts of my job. Those conversations often yield new perspectives on the topics we know, and we dive into new ideas together. I had one of those conversations recently when a client asked, “We know research must have a clear objective, must be actionable, and should be aligned with business goals, but is there more to consider? What does ‘good’ research look like?”

This thoughtful question turned into an opportunity to reconsider what we know about research and delve into best practices that I’ve been hearing from research teams and leaders. Yes, research must have clear objectives, use the right methodology, and be actionable to have impact. These are well-known qualities of good research. There are also more subtle qualities that we don’t always talk about but are crucial to making research successful. For now, I’ll focus on three of those qualities. In addition to having clear objectives, sound methodology, and being actionable, good research must also be:

Connected . In successful organizations, research connects to customers, stakeholder and business goals, and previous research findings. Those organizations connect to customers by observing their behavior and getting direct feedback from them. Research connects to stakeholder and business goals through a shared approach to decision-making and effective research partnerships that facilitate collaboration. These partnerships improve buy-in for research and make research an irrevocable part of decision-making. Successful teams systematically review past research to identify what is already known and where the gaps lie. This helps teams avoid doing repetitive work and focuses research on the gaps that haven’t been examined yet.
Continuous. Successful teams realize that customer research is an iterative process guiding decisions from discovery to creation and execution ; it’s not a one-time activity to validate product decisions that have already been made. Expertise guides the process, and research is conducted at various levels, from strategic to tactical, on a regular schedule. An agreed-upon research cadence that documents the type of research activities and their frequency (e.g., discovery research at the start of each quarter and evaluative research every two weeks) helps define roles and responsibilities, as well as when researchers and stakeholders should come together to make decisions.
Timely. I often hear from research teams that their findings are not utilized due to time pressure or changing priorities in the organization. To drive decisions and be actionable, research must be conducted at the right time, while it can still help decision-making — and that requires careful planning that gives you the ability to pivot and reframe your scope when circumstances change. A research and insights leader at a leading software company said that when they’re planning for a discovery project, they aim to finish it at a time where it’s going to be particularly useful so that it doesn’t just sit on a shelf.

Let’s Connect

What other qualities do you believe are integral to successful research? If you’re a Forrester client and would like to learn more about research best practices or want to share examples of what good research looks like in your organization, let’s connect. You can set up a conversation with me  here . You can also  follow or connect with me on LinkedIn .

Thanks for signing up.

Stay tuned for updates from the Forrester blogs.

Use Journey Maps To Kick-Start A CX Transformation

This complimentary guide will show you how to leverage customer journey maps to spur investment and interest in cx, as well as boost performance., prioritize accessibility in procurement for better cx and ex, unlocking the future of mobile banking: insights from forrester’s 2024 european digital experience review™, get the insights at work newsletter, help us improve.

An official website of the United States government

Here’s how you know

Official websites use .gov A .gov website belongs to an official government organization in the United States.

Secure .gov websites use HTTPS A lock ( Lock A locked padlock ) or https:// means you’ve safely connected to the .gov website. Share sensitive information only on official, secure websites.

https://www.nist.gov/blogs/taking-measure/keepers-right-answer-why-measurements-nist-are-important-nation-and-world

Taking Measure

Just a Standard Blog

Keepers of the Right Answer: Why Measurements at NIST Are Important for the Nation and the World

NIST Chief Metrologist Jim Olthoff stands in front of equipment in a lab.

Practically everything you use in your everyday life works because of measurement science. Without precise measurements, your car wouldn’t run, your phone wouldn’t work, hospitals couldn’t function, and the ATM would fail.

NIST is the national measurement institute of the United States. Most people in the U.S. have no idea that there is a single organization within the federal government that makes sure all measurements in the U.S. are correct and trustworthy — and that they are accepted by other governments worldwide.

What does that look like in practice? Here’s an example.

More than 40 million mammograms are done in the U.S. each year. Each one is a chance to save a life.

Those mammograms have to be both safe and effective, so mammography machines must expose patients to the smallest amount of radiation needed to get a good image, thereby minimizing any harmful effects. Careful measurements ensure that the benefits of the test far outweigh the impact of a minuscule exposure. We know that U.S. hospitals achieve this balance because they trace that radiation amount back to one of our labs here at NIST.

Traceability is a complex scientific concept, but it essentially means that in comparison to precise standards calibrated at NIST, the mammography machine accurately delivers the exact amount of radiation allowed. We know this because the chain of calibration — or all the steps it took to test and check that machine — can be linked all the way back to one of our radiation physics labs here in Gaithersburg, Maryland.

This is one of many hundreds of examples of how measurement science, also known as metrology, affects daily life — whether you think about it or not.

Some of these examples are obvious. When you fill up your car’s gas tank or buy deli meat, you know exactly how much you’re buying because the state weights and measures offices check the pumps and scales for accuracy, based on the volume and mass standards from NIST.

Perhaps less obvious is that the values on the nutrition labels on food packaging are determined by comparing the values to the food standards that NIST produces . Even less obvious is the fact that your GPS works because of the atomic clocks inside the satellites. NIST created the world’s first atomic clock and remains a world leader in making these ultraprecise timekeepers.

Why Measurement Science Matters

NIST SRM 2387, Peanut Butter, with white bread

These examples — and many more complicated ones — are why we have a national organization focused on metrology. We have thousands of researchers, known as metrologists, constantly figuring out how to measure things better.

Why such dedication? Well, everything in science and technology is based on measurement. In science, the ability to measure something and determine its value — and to do so in a repeatable and reliable way — is essential.

For example, precision measurements enable weather forecasting to happen. While you may notice it more when the weather forecasts aren’t quite right, five-day weather forecasts are now accurate about 90% of the time .

One tool meteorologists (as opposed to metrologists) use to predict the weather is measuring the energy — or radiation — that’s coming from Earth. Recent advances in our ability to make these measurements more accurately have contributed to our ever-improving ability to predict what your weekend weather will be like.

Additionally, the more science and technology advance, the trickier the measurements become.

For example, when scientists in the late 1940s created transistors — which have become the building block of computers and virtually all modern electronics — they had to measure them on the scale of the millimeter, which is about the thickness of a dime.

As semiconductor technology has advanced, we now have to measure computer chips at the scale of nanometers — one million times smaller than the width of that dime. So, if measurement science didn’t improve, technology couldn’t advance. Without it, we would not have the latest smartphones we take for granted today.

An additional challenge is that we’re now in a world where day-to-day measurements are tied to physical constants in nature , not to things. This makes measurements more universal and consistent and also more complicated for scientists to define.

For example, before 2018, all mass measurements were traceable to a metal cylinder held in a vault in France. Now, mass is determined by a physical constant in nature — known as the Planck constant . While this new approach has many benefits, it’s also more complex. In fact, researchers here at NIST are collaborating with our counterparts in Germany to work out some of the remaining challenges with this particular measurement.

One of the things I love about working in metrology is that there is a correct answer to any measurement question. If we are careful enough and understand the science well enough, then we will get a reliable answer. We will also be able to know how sure we are of the accuracy or correctness of the answer, which we call “uncertainty.”

One of the roles we play at NIST is to provide those answers in a trustworthy way; that’s why I call us the “keepers of the right answer.” If someone needs to know a temperature, what time it is , how pure something is, or how small something is, they know they can trust the science that comes out of NIST.

I’m proud to be a part of that process and to have helped lead the organization that inspires trust across the world.

From Physicist to Global Metrologist

In school, I studied atomic and molecular physics, and I knew I wanted to work in a laboratory.

When I drove up to my first day at NIST a few decades ago and parked outside of the metrology building, I realized I had no idea what the word “metrology” meant.

I went to my office and looked up the word in the dictionary. I learned it meant the science of measurement. That’s interesting, I thought.

I went on to do physics research in my lab in support of the semiconductor and electricity industries. These experiments obviously involved measurements, as all science does, but honestly, they were not the focus of my thinking.

It wasn’t until I was asked to work on calibrations that the importance and beauty of measurements became clear to me. Working on calibrating electrical transformers and capacitors (devices that store energy), I delved into the world of traceability. I saw how important and universal the world of metrology was.

One of the most exciting outcomes of my engagement with calibrations was that I became involved in the international world of metrology. Other countries have their own versions of NIST — other national metrology institutes — that handle their own weights, measures, timekeeping and related areas of science.

6 people standing on a stage in front of a screen that reads: 26th CGPM

There’s an enormous international infrastructure among the countries of the world and their national metrology institutes to make sure the way things are measured in the U.S. is acceptable in other countries and vice versa. This is essential for issues like repairing airplanes or buying materials for your company across the globe.

As the chief metrologist for the United States, I personally get to see the importance of this global cooperation and to be a part of a worldwide community of metrologists. While to many this world of measurements may seem mundane or even boring, there are so many exciting things happening.

The redefinition of the second is expected to come in a few years. (This will be big for metrologists, but don’t worry, you’re unlikely to notice.) New measurements to monitor the climate are being developed and deployed. Techniques to unravel the mysteries of bioengineering are advancing. Ways to accurately measure the presence and impact of microplastics are being developed, and so much more.

As technology advances and demands more from measurement science, we will be here to provide it. It is really an exciting time to be a metrologist!

Be a Metrologist

Since it’s an exciting time to be a metrologist, come join us here at NIST:

NIST Careers
NIST Internships

About the author

James K. Olthoff

James K. Olthoff is NIST’s first chief metrologist and serves as the primary representative both nationally and internationally of NIST’s role as the national metrology institute of the United States. He works with NIST leadership to ensure that NIST’s core measurement capabilities remain among the best in the world. Dr. Olthoff has served in many leadership positions at NIST including the associate director for laboratory programs and acting NIST director. He received his Ph.D. in physics from the University of Maryland and did postdoctoral research at The Johns Hopkins School of Medicine before coming to NIST almost 40 years ago.

A researcher wearing a lab coat uses tongs to place a silvery sphere into a large scientific device as another researcher looks on.

One of the World’s Roundest Objects Is Helping to Build a Better Mass Measurement

You Don’t Learn This in School: My Experience as a NIST Summer Intern

Measurement in the Movies

Great article! Very informative and interesting I would love to receive all of the updates and data of your research and measurement findings in all areas great job! Tammy

Thanks for your kind words! If you would like to receive NIST news and updates directly to your inbox, you can visit the link here to sign up for our email bulletins on your choice of NIST topics: https://public.govdelivery.com/accounts/USNIST/subscriber/new

I started working in high tech in 1976 building scanning electron microscopes, SEMs. I was told that one of our earlier deliveries of the AutoScan was to the National Bureau of Standards, NBS that is now NIST, and that the SEM was used to define the micrometer, commonly referred to as the micron. I was, and am still proud to be associated with that use of our systems, and still follow NIST . (As a high school student I used to listen to NBS WWV @5mhz time broadcasts!) This was a long second to write up, but I know it will be an accurate timing.

Thanks so much for sharing your story, and for your work on scanning electron microscopes! SEMs are still cutting-edge instruments for so many applications at NIST. We are glad that you are a part of our history!

Add new comment

No HTML tags allowed.
Web page addresses and email addresses turn into links automatically.
Lines and paragraphs break automatically.

Numbers, Facts and Trends Shaping Your World

Read our research on:

Full Topic List

Regions & Countries

Publications
Our Methods
Short Reads
Tools & Resources

Read Our Research On:

In Tied Presidential Race, Harris and Trump Have Contrasting Strengths, Weaknesses

2. issues and the 2024 election, table of contents.

Other findings: An uncertain election outcome, the more critical candidate, Trump and the 2020 election
Voting preferences among demographic groups
Support for Harris, Trump among voters and nonvoters in recent elections
How Harris and Trump supporters see their vote
Do voters think it’s clear who will win?
Most voters cite several issues as very important to their vote
Changes in confidence in candidates on issues, following Biden’s departure from race
Do voters see the candidates as ‘too personally critical’?
Do the candidates make you feel proud, hopeful, uneasy or angry?
How the candidates make Harris and Trump supporters feel
How men and women view the impact of the candidates’ genders
Views of the candidates’ races and ethnicities
Views of the candidates’ ages among younger and older voters
Views of the values and goals of the other candidate’s supporters
Should the president work with the opposing party in Congress?
Top economic concerns: Food and consumer prices, housing costs
Acknowledgments
The American Trends Panel survey methodology

As concerns around the state of the economy and inflation continue, about eight-in-ten registered voters (81%) say the economy will be very important to their vote in the 2024 presidential election.

While the economy is the top issue among voters, a large majority (69%) cite at least five of the 10 issues asked about in the survey as very important to their vote.

Chart shows The economy is the top issue for voters in the 2024 election

There are wide differences between voters who support Harris and Trump when it comes to the issues.

Among Trump supporters, the economy (93%), immigration (82%) and violent crime (76%) are the leading issues. Just 18% of Trump supporters say racial and ethnic inequality is very important. And even fewer say climate change is very important (11%).

For Harris supporters, issues such as health care (76%) and Supreme Court appointments (73%) are of top importance. Large majorities also cite the economy (68%) and abortion (67%) as very important to their vote in the election.

Most voters cite several issues as very important to their vote this November. Very few – just 5% – say only one issue or no issues are highly important.

Chart shows About 7 in 10 voters say 5 or more issues are very important to their presidential vote

Majorities of both Harris supporters (71%) and Trump supporters (69%) say at least five of 10 issues included in the survey are very important to their vote.

Harris supporters are more likely than Trump supporters to say most of the issues included are very important. About a third of Harris supporters (32%) say at least eight of 10 issues are very important, compared with 17% of Trump supporters.

Top voting issues: 2020 versus 2024

While the economy has long been a top issue for voters – and continues to be one today – other issues have become increasingly important for voters over the past four years.

Immigration

About six-in-ten voters (61%) today say immigration is very important to their vote – a 9 percentage point increase from the 2020 presidential election and 13 points higher than during the 2022 congressional elections.

Immigration is now a much more important issue for Republican voters in particular: 82% of Trump supporters say it is very important to their vote in the 2024 election, up 21 points from 2020.

About four-in-ten Harris supporters (39%) say immigration is very important to their vote. This is 8 points higher than the share of Democratic congressional supporters who said this in 2022, but lower than the 46% of Biden supporters who cited immigration as very important four years ago.

In August 2020, fewer than half of voters (40%) said abortion was a very important issue to their vote. At the time, Trump voters (46%) were more likely than Biden voters (35%) to say it mattered a great deal.

Following the Supreme Court’s decision to overturn Roe v. Wade , opinions about abortion’s importance as a voting issue shifted. Today, 67% of Harris supporters call the issue very important – nearly double the share of Biden voters who said this four years ago, though somewhat lower than the share of midterm Democratic voters who said this in 2022 (74%). And about a third of Trump supporters (35%) now say abortion is very important to their vote – 11 points lower than in 2020.

Confidence in Harris and Trump on top issues

Chart shows Voters are more confident in Trump on economy, immigration; Harris leads on abortion, race

Voters have more confidence in Trump than Harris on economic, immigration and foreign policies. Half or more voters say they are at least somewhat confident in Trump to make good decisions in these areas, while smaller shares (45% each) say this about Harris.

In contrast, voters have more confidence in Harris than Trump to make good decisions about abortion policy and to effectively address issues around race. Just over half of voters have confidence in Harris on these issues, while 44% have confidence in Trump on these issues.

Trump holds a slight edge over Harris for handling law enforcement and criminal justice issues (51% Trump, 47% Harris). Voters are equally confident in Harris and Trump to select good nominees for the Supreme Court (50% each).

Fewer than half of voters say they are very or somewhat confident in either candidate to bring the country closer together (41% are confident in Harris, 36% in Trump). And voters express relatively little confidence in Trump (37%) or Harris (32%) to reduce the influence of money in politics.

Chart shows Voters are more confident in Harris than they were in Biden on several issues

Since Biden dropped out of the presidential race in July , there has been movement on how confident voters are in the candidates to address issues facing the country.

Abortion policy

In July, 48% of voters were confident in Biden to make good decisions about abortion policy. Today, 55% of voters are confident in Harris to do the same.

Harris currently has an 11-point advantage over Trump on voters’ confidence to handle abortion policy decisions.

Immigration policy

Voters also express more confidence in Harris to make wise decisions about immigration policy than they did for Biden before he withdrew from the race. Today, 45% are confident in Harris on this issue; in July, 35% said this about Biden.

While Trump’s advantage over Harris on immigration policy is less pronounced than it was over Biden, he continues to hold a 7-point edge. Voters are as confident in his ability to make wise decisions about immigration policy as they were in July (52%).

Foreign and economic policies

Harris has also improved over Biden in voters’ confidence to make good decisions about foreign and economic policies. Currently, 45% of voters are confident in Harris on each of these issues.

In July, 39% had confidence in Biden to make good foreign policy decisions, while a similar share (40%) had confidence in him on economic policy.

Trump holds an edge over Harris on both of these issues, though both are somewhat narrower than the advantage he had over Biden on these issues in July.

Sign up for our weekly newsletter

Fresh data delivery Saturday mornings

Sign up for The Briefing

Weekly updates on the world of news & information

Donald Trump
Election 2024
Kamala Harris
Political Issues
Political Parties
Voter Demographics

The Political Values of Harris and Trump Supporters

As robert f. kennedy jr. exits, a look at who supported him in the 2024 presidential race, harris energizes democrats in transformed presidential race, many americans are confident the 2024 election will be conducted fairly, but wide partisan differences remain, joe biden, public opinion and his withdrawal from the 2024 race, most popular, report materials.

September 2024 Presidential Preference Detailed Tables
Questionnaire

901 E St. NW, Suite 300 Washington, DC 20004 USA (+1) 202-419-4300 | Main (+1) 202-857-8562 | Fax (+1) 202-419-4372 | Media Inquiries

Research Topics

Email Newsletters

ABOUT PEW RESEARCH CENTER Pew Research Center is a nonpartisan, nonadvocacy fact tank that informs the public about the issues, attitudes and trends shaping the world. It does not take policy positions. The Center conducts public opinion polling, demographic research, computational social science research and other data-driven research. Pew Research Center is a subsidiary of The Pew Charitable Trusts , its primary funder.

Skip to primary navigation
Skip to main content
Skip to primary sidebar
Skip to footer

The Center for Compassion and Altruism Research and Education

If you want to lead, compassion and mindfulness are the keys!

September 9, 2024 by Sounak Chakrabarty

Written By Sounak Chakrabarty

Mindfulness and Compassion Are Fundamental for Leadership

My journey as a leader has been profoundly influenced by my applied compassion training through CCARE Stanford. Almost two decades of working with several organizations has made me understand that true change needs to be ‘inside-out’ and that it begins with each individual.

Witnessing the challenges and suffering people face in organizations, my vision became clear: to facilitate the meaningful change that people, teams, and organizations aspire to, mindfulness, compassion, and neuroscience need to be integrated into organizational leadership.

In today’s complex and uncertain world, leaders are entrusted with navigating challenges, inspiring teams, and fostering a positive organizational culture. To achieve these goals, compassion and mindfulness are not merely desirable qualities but essential ones.

Compassion, often defined as empathy with action, goes beyond understanding others’ suffering. It involves taking concrete actions to alleviate the suffering of any kind and to promote well-being. We need to consider the word “suffering” in a broader sense: it could mean a challenge, an unpleasantness or even unsatisfactoriness. This requires a deeper understanding of those around us and a willingness to go beyond empathy and take action.

Mindfulness is the foundation for compassion: without noticing and recognizing suffering, can we practice compassion? Mindfulness is the practice of being aware of the present moment. By cultivating mindfulness, leaders can better notice and recognize suffering, both within themselves and in others. This awareness enables them to respond to suffering with action, which is compassion.

Why is Compassion Essential for Leadership?

Navigating the VUCA world: The acronym VUCA (Volatile, Uncertain, Complex, and Ambiguous) aptly describes the modern business landscape. Effective leaders must be able to manage uncertainty, navigate change, inspire their teams, and achieve results. Compassion plays a vital role in this context.
Self-awareness and self-compassion: Before leading others, leaders must first lead themselves. This means to understand and accept themselves. Self-compassion is essential not only for acceptance, but for managing one’s own emotions, habits, and actions. It helps us to embrace our humanity and bounce back from setbacks or failures, which is an integral part of the leadership journey.
Fostering trust and relationships: When employees/teams feel valued, understood, and supported, they are more likely to be engaged, productive, and loyal, and that’s why for leaders, compassion is crucial. Compassion fosters trust, nurtures relationships and builds a supportive environment.

My participation in the applied compassion training program at CCARE led to significant personal and professional growth. I developed a deeper sense of self-belief and confidence, gained valuable insights into action-oriented leadership, and recognized the immense responsibility that comes with leadership.

Compassionate Leadership Development in Organizations

As part of my capstone project for the ACT program at CCARE, I created an intervention called Compassionate Leadership Development in Organizations , which includes:

A model of Employee Thriving, which focuses on creating a positive and supportive work environment.
Compassionate Leadership Assessment tools for senior leaders, and
A 2-day in-person immersive leadership workshop called CALM (Compassionate Actions in Leadership with Mindfulness).

This intervention prepares and trains leaders to enhance compassionate leadership for creating a better employee experience and competitive advantage for their organization.

Apart from Compassionate Leadership at the organization, I have also created a highly-rated 5-day immersive mindfulness retreat in the Himalayas called SMILE ( S hine with M indfulness I nspired L eadership and E motional Intelligence). This retreat aims to equip leaders with the tools and skills to cultivate mindfulness, compassion, emotional intelligence, and overall well-being, to drive personal growth and fulfilment at work life.

In an era marked by uncertainty and complexity, compassionate leadership is more essential than ever. By cultivating mindfulness and compassion, leaders can create a positive organizational culture, foster employee well-being, and drive meaningful change. My journey through the ACT program at CCARE has reinforced the power of compassion to transform individuals and organizations. As an Ambassador of Applied Compassion, I am dedicated to sharing these insights and inspiring others to embrace a more compassionate and mindful approach to leadership and life at large.

About Sounak Chakrabarty

Sounak Chakrabarty is a learner, practitioner, and teacher of Mindfulness and Compassion. He is the founder of Hi Happy Monk , a mindfulness and neuroscience-based start-up from India. During his two decades of professional experience, he’s led organizations and consulted MNCs in the space of Leadership, Learning, and Organizational Development. Sounak is a management postgraduate, and an alumnus of Google’s Search Inside Yourself, the MBSR Program of the University of Massachusetts, and the Positive Psychiatry & Mental Health program from Sydney University. He is an alumnus of the Applied Compassion Training formerly offered through CCARE Stanford.

Reader Interactions

Professionals
| “Et ‘two,’ GAO?”: Recent Sustain on the Rule of Two Reminds Agencies of the Importance of Accurate Market Research

“Et ‘two,’ GAO?”: Recent Sustain on the Rule of Two Reminds Agencies of the Importance of Accurate Market Research

What you need to know.

Key takeaway # 1

The Rule of Two and its interplay with the nonmanufacturing rule can have implications for all government contractors—not just small businesses. Although most Rule of Two protests are lodged by small businesses, there are situations where large businesses may leverage Rule of Two arguments to advocate in favor of competing a procurement on an unrestricted basis.

Key takeaway # 2

Small businesses should also keep in mind that Rule of Two protests can be used to challenge set-aside restrictions that are overly burdensome, as was the case in Knudsen.

Client Alert | 3 min read | 09.11.24

For the first time in nearly a decade, GAO in Knudsen Systems, Inc. sustained a protest challenging an agency’s decision to set aside a procurement for small businesses. The decision involves the so-called “Rule of Two”: under FAR 19.502-2(b), agencies must set aside for small businesses a procurement with an anticipated dollar value of more than $150,000 where the agency’s market research demonstrates there is a reasonable expectation at least two responsible small business offerors can meet the agency’s requirements at a fair market price.

Rule of Two protests can come in two flavors. The more common variety is a small business challenging an agency’s failure to conduct adequate market research and issue a procurement as a small business set aside pursuant to the Rule of Two. The less common variety involves an “other than small” protester alleging the procurement should be competed on an unrestricted basis, and that an agency’s decision to set aside the procurement is not supported by a rational Rule of Two analysis. Over nine years ago, GAO sustained such a protest in Triad Isotopes, Inc. , concluding that the agency’s market research was insufficient to support the agency’s conclusion that it would likely receive quotes from at least two responsible small business concerns at a fair market price. In Triad , GAO noted that an agency’s analysis must address not only the existence of small businesses that might submit proposals but also their capability to perform the contract. That analysis may also require consideration of whether the nonmanufacturer rule applies to the procurement. (The nonmanufacturer rule generally requires that, in procurements set aside for small businesses, if the awardee does not manufacture the product itself, it must provide products from a domestic small business manufacturer or processor—or obtain a waiver of the requirement.) As explained in Triad, if the nonmanufacturer rule applies to the procurement, then the agency’s assessment must consider the companies’ ability to comply—small businesses unable to comply with the nonmanufacturer rule may not be considered capable of performing the contract.

GAO’s recent decision in Knudsen Systems, Inc. involves similar facts. In Knudsen , the Navy sought to buy SONAR equipment under a small business set-aside. The Navy believed initially that a nonmanufacturer rule waiver had been issued for the equipment and, accordingly, the agency’s Rule of Two market research included sources-sought notices that (incorrectly) advised potential offerors that the nonmanufacturer rule did not apply. After receiving information from three small businesses indicating that they could meet the solicitation’s requirements at a fair market price, the agency decided to set aside the procurement for small businesses.

In the midst of the procurement, the Navy learned that the nonmanufacturer rule waiver did not apply to the procurement— i.e. , the nonmanufacturer rule did apply. The Navy amended the solicitation to include the nonmanufacturer rule but decided that the procurement would remain a small business set-aside.

Knudsen was a small business offeror who planned to supply equipment it sourced from a Canadian manufacturer but, following the Navy’s solicitation amendment to include the nonmanufacturer rule, could no longer bid on the procurement. Knudsen filed a protest with GAO, challenging the Navy’s decision to conduct the procurement as a small business set-aside. Knudsen argued the Navy’s Rule of Two analysis was flawed because it failed to consider the “capability” of small businesses to comply with the nonmanufacturer rule. GAO agreed, noting that the Navy’s initial decision to set aside the procurement for small businesses was premised on an erroneous assumption (that the procurement was eligible for a nonmanufacturer rule waiver), which resulted in flawed market research. In the end, GAO sustained the protest because there was “no support for the contracting officer’s assumption that any of the companies identified in the market research report were capable of performing the amended solicitation requirements.”

We would like to thank Cherie J. Owen, Consultant, for her contribution to this alert.

Amy Laderberg O'Sullivan

D | +1.202.624.2563

YW9zdWxsaXZhbkBjcm93ZWxsLmNvbQ==

Olivia Lynch

D | +1.202.624.2654

b2x5bmNoQGNyb3dlbGwuY29t

Issac D. Schabes

D | +1.202.654.6706

aXNjaGFiZXNAY3Jvd2VsbC5jb20=

Client Alert | 5 min read | 09.11.24

California to Empower Attorney General with Increased Authority to Ensure Cities Comply with State Housing Laws

California Governor Gavin Newsom announced his plans to sign Senate Bill 1037, a bill designed in response to the “statewide housing shortage crisis” that will give Attorney General Rob Bonta new civil penalty authority to hold municipalities accountable from the moment they purportedly first violate the state’s housing laws. This marks a significant change in the law. ...

Client Alert | 8 min read | 09.11.24

The EU Batteries Regulation: Taking Stock of the New EU Battery Requirements

Client Alert | 7 min read | 09.11.24

The Month in International Trade – August 2024

Client Alert | 4 min read | 09.09.24

Flag on the Play: SEC Fines Adviser for Insufficient MNPI Controls in CLO Trades

View All Insights

to the latest insights from our team

Subscribe Now

Today's news
Reviews and deals
Climate change
2024 election
Newsletters
Fall allergies
Health news
Mental health
Sexual health
Family health
So mini ways
Unapologetically
Buying guides

Entertainment

How to Watch
My watchlist
Stock market
Biden economy
Personal finance
Stocks: most active
Stocks: gainers
Stocks: losers
Trending tickers
World indices
US Treasury bonds
Top mutual funds
Highest open interest
Highest implied volatility
Currency converter
Basic materials
Communication services
Consumer cyclical
Consumer defensive
Financial services
Industrials
Real estate
Mutual funds
Credit cards
Balance transfer cards
Cash back cards
Rewards cards
Travel cards
Online checking
High-yield savings
Money market
Home equity loan
Personal loans
Student loans
Options pit
Fantasy football
Pro Pick 'Em
College Pick 'Em
Fantasy baseball
Fantasy hockey
Fantasy basketball
Download the app
Daily fantasy
Scores and schedules
GameChannel
World Baseball Classic
Premier League
CONCACAF League
Champions League
Motorsports
Horse racing

New on Yahoo

Privacy Dashboard

New couples should reveal their salaries after eight dates, according to research

New couples reveal their salaries after eight dates, according to research. However, the survey of 2,000 adults found half believe disclosing your income to a new partner is one of the most awkward conversations daters can have. But 55 per cent think it is important to be transparent about incomes at this stage – as 45 per cent believe it can build trust. On the other hand, 48 per cent of those who disagree want couples to focus on emotional connection rather than finances when the romance is in its infancy. The research was commissioned by Skipton, which has been in London during UK Savings Week with its ‘Money Talks Booth’ challenging couples to take the awkwardness out of money chat and blindly share their financial confession with an expert on hand.

IMAGES

Reasons Why Research Is Important
Why is Research Important for Undergraduate Students?
What is Research?
Academic Research: Its Importance & Ways to Conduct
What is research
15 Reasons Why Research Is Important

VIDEO

Importance of Research
Research Profile 1: Why is it so important?
What is research
Buddhist Philosophy for Enhancing well-being in Modern Society
“Buddhist Philosophy for Enhancing well-being in Modern Society”
What is the best research? How to write a Research paper? Procedure, kinds and styles in Research

COMMENTS

7 Reasons Why Research Is Important
Why Research Is Necessary and Valuable in Our Daily Lives. It's a tool for building knowledge and facilitating learning. It's a means to understand issues and increase public awareness. It helps us succeed in business. It allows us to disprove lies and support truths. It is a means to find, gauge, and seize opportunities.
What Is the Importance of Research? 5 Reasons Why Research is Critical
Builds up credibility. People are willing to listen and trust someone with new information on one condition - it's backed up. And that's exactly where research comes in. Conducting studies on new and unfamiliar subjects, and achieving the desired or expected outcome, can help people accept the unknown.
2.1 Why is Research Important
Discuss how scientific research guides public policy. Appreciate how scientific research can be important in making personal decisions. Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people's authority, and blind luck.
2.1 Why Is Research Important?
Discuss how scientific research guides public policy. Appreciate how scientific research can be important in making personal decisions. Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people's authority, and blind luck.
10 Reasons Why Research is Important
Research unlocks the unknowns, lets you explore the world from different perspectives, and fuels a deeper understanding. In some areas, research is an essential part of success. In others, it may not be absolutely necessary, but it has many benefits. Here are ten reasons why research is important: #1. Research expands your knowledge base.
Explaining How Research Works
Placing research in the bigger context of its field and where it fits into the scientific process can help people better understand and interpret new findings as they emerge. A single study usually uncovers only a piece of a larger puzzle. Questions about how the world works are often investigated on many different levels.
What is Research? Definition, Types, Methods, and Examples
The research process collects accurate information systematically. Logic is used to analyze the collected data and find insights. Checking the collected data thoroughly ensures accuracy. Research also leads to new questions using existing data. Accuracy is key in research, which requires precise data collection and analysis.
PSYCH101: Why Research Is Important
Why Research Is Important. Read this text, which introduces the scientific method, which involves making a hypothesis or general premise, deductive reasoning, making empirical observations, and inductive reasoning, Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely ...
Purpose of Research
The importance of research lies in its ability to generate new knowledge and insights, to test existing theories and ideas, and to solve practical problems. Some of the key reasons why research is important are: Advancing knowledge: Research is essential for advancing knowledge and understanding in various fields. It enables us to explore and ...
What is the importance of research in everyday life?
Research empowers us with knowledge. Though scientists carry out research, the rest of the world benefits from their findings. We get to know the way of nature, and how our actions affect it. We gain a deeper understanding of people, and why they do the things they do. Best of all, we get to enrich our lives with the latest knowledge of health ...
Significance of Research: Meaning, Importance & Examples
It helps us advance knowledge and develop new technologies. Research is essential to the academic community, as it helps scholars build on previous knowledge and advance their understanding of the world. It is also important to the general public, as it can help solve problems and improve our quality of life.
What Is Research, and Why Do People Do It?
You will also learn much more about the issue of research importance when you read Chap. 5. Exercise 1.7. Identify a problem in education that is closely connected to improving learning opportunities and a problem that has a less close connection. For each problem, write a brief argument (like a logical sequence of if-then statements) that ...
8 Reasons Why Research is Important and Steps to Conduct Research
4. Builds Credibility. Building credibility in your profession via research is beneficial. You show your knowledge and competence on a subject when you undertake research and publish your results. This might offer new professional growth and development prospects by establishing you as an authority in your sector.
PDF Why research is important
en research and learning. Experiential knowing, or 'knowing how', can be a valuable outcome of an inquiry process, but research always involves. ommunication with others. Learning can occur at an individual, intuitive level, but research requires the sym-bolisation and transmission of these understand.
What is Research? Definition, Types, Methods and Process
Research is defined as a meticulous and systematic inquiry process designed to explore and unravel specific subjects or issues with precision. This methodical approach encompasses the thorough collection, rigorous analysis, and insightful interpretation of information, aiming to delve deep into the nuances of a chosen field of study.
Why does research matter?
Abstract. A working knowledge of research - both how it is done, and how it can be used - is important for everyone involved in direct patient care and the planning & delivery of eye programmes. A research coordinator collecting data from a health extension worker. ethiopia. The mention of 'research' can be off-putting and may seem ...
Why should I do research? Is it a waste of time?
Research is the most important activity to achieve scientific progress. Although it is an easy process on a theoretical basis, practically it is a laborious process, and full commitment and dedication are of paramount importance. Currently, given that the financial crisis has a key influence in daily practice, the need to stress the real ...
Significance of the Study
Significance of the study in research refers to the potential importance, relevance, or impact of the research findings. It outlines how the research contributes to the existing body of knowledge, what gaps it fills, or what new understanding it brings to a particular field of study. In general, the significance of a study can be assessed based ...
Six Reasons Why Research is Important
Research helps you expand on any prior knowledge you have of the subject. The research process creates new opportunities for learning and progress. 2- Research Helps in Problem-solving. The goal of the research is to broaden our understanding. Research gives us the information and knowledge to solve problems and make decisions.
The Role Of Research At Universities: Why It Matters
Strength in research helps to define a university's "brand" in the national and international marketplace, impacting everything from student recruitment, to faculty retention, to attracting ...
What is Research Ethics?
In discussing or teaching research ethics, it is important to keep some basic distinctions in mind. Prescriptive vs. descriptive claims. It is important not to confuse moral claims about how people ought to behave with descriptive claims about how they in fact do behave. From the fact that gift authorship or signing off on unreviewed data may ...
Why Is Research Important?
Appreciate how scientific research can be important in making personal decisions. Scientific research is a critical tool for successfully navigating our complex world. Without it, we would be forced to rely solely on intuition, other people's authority, and blind luck. While many of us feel confident in our abilities to decipher and interact ...
What Does Good Research Look Like? Three Hallmarks Of Successful
An agreed-upon research cadence that documents the type of research activities and their frequency (e.g., discovery research at the start of each quarter and evaluative research every two weeks) helps define roles and responsibilities, as well as when researchers and stakeholders should come together to make decisions. Timely.
8 student benefits of a research-intensive university
"Research experience can help make students more competitive for graduate or professional schools by preparing them for graduate thesis or capstone projects," Rawlinson said. "Ultimately, involvement in research makes students more well-rounded learners." 3. The chance to learn from the faculty who generate the science that informs practice
Keepers of the Right Answer: Why Measurements at NIST Are Important for
I went on to do physics research in my lab in support of the semiconductor and electricity industries. These experiments obviously involved measurements, as all science does, but honestly, they were not the focus of my thinking. It wasn't until I was asked to work on calibrations that the importance and beauty of measurements became clear to me.
Issues and the 2024 election
And even fewer say climate change is very important (11%). For Harris supporters, issues such as health care (76%) and Supreme Court appointments (73%) are of top importance. Large majorities also cite the economy (68%) and abortion (67%) as very important to their vote in the election. Most voters cite several issues as very important to their ...
If you want to lead, compassion and mindfulness are the keys!
Sounak Chakrabarty is a learner, practitioner, and teacher of Mindfulness and Compassion. He is the founder of Hi Happy Monk, a mindfulness and neuroscience-based start-up from India.During his two decades of professional experience, he's led organizations and consulted MNCs in the space of Leadership, Learning, and Organizational Development.
How Newly Identified Biomarkers Could Reveal Risk Factors for SIDS
More research is needed, but this could one day help to prevent SIDS. "This study suggests that metabolic factors may play a crucial role in SIDS," said Scott Oltman, MS, an epidemiologist at UCSF and first author of the study. "These patterns could help identify children at higher risk, potentially saving lives in the future."
"Et 'two,' GAO?": Recent Sustain on the Rule of Two Reminds Agencies of
For the first time in nearly a decade, GAO in Knudsen Systems, Inc. sustained a protest challenging an agency's decision to set aside a procurement for small businesses. The decision involves the so-called "Rule of Two": under FAR 19.502-2(b), agencies must set aside for small businesses a procurement with an anticipated dollar value of more than $150,000 where the agency's market ...
New couples should reveal their salaries after eight dates ...
New couples reveal their salaries after eight dates, according to research. However, the survey of 2,000 adults found half believe disclosing your income to a new partner is one of the most ...

What Is the Importance of Research? 5 Reasons Why Research is Critical

The Importance Of Health Research

What Is The Importance Of Clinical Research?

Five Reasons Why Research is Critical

The Importance Of Research To Students

The Importance Of Research Methodology

The Importance Of Qualitative Research

The Process Of Scientific Research

What Is The Importance Of Research In Everyday Life?

Related Articles:

Featured Articles

2.1 Why is Research Important

USE OF RESEARCH INFORMATION

THE PROCESS OF SCIENTIFIC RESEARCH

Answers to Exercises

Share This Book

2.1 Why Is Research Important?

Use of Research Information

Link to Learning

NOTABLE RESEARCHERS

The Process of Scientific Research

10 Reasons Why Research is Important

#1. Research expands your knowledge base

#3. Research helps you know what you’re up against

#4. Research builds your credibility

#5. Research helps you narrow your scope

#6. Research teaches you better discernment

#7. Research introduces you to new ideas

#8. Research helps with problem-solving

#9. Research helps you reach people

#10. Research encourages curiosity

You are here

Explaining How Research Works

Connect with Us

What is Research? Definition, Types, Methods, and Examples

Why is research important?

What is the purpose of research?

What are the characteristics of research?

Types of research

Types of research methods

Basic steps involved in the research process

How to ensure research accuracy?

Related Posts

Join Us for Peer Review Week 2024

How Editage All Access is Boosting Productivity for Academics in India

PSYCH101: Introduction to Psychology

Use of Research Information

Notable Researchers

The Process of Scientific Research

What is the importance of research in everyday life?

Research increases the quality of life

Research empowers us with knowledge

Research drives progress forward

Popular stories

Money isn’t everything. For this Tasmania-trained architect, improving society is his #1 goal.

The prestigious education of Japan’s royal family

6 cheapest universities in Europe to study medicine

International PhD students now eligible for UK Research and Innovation scholarships

International scholars make lasting contributions to the US: report

Work Abroad

Abstractspiepr Abs1

Part I. What Is Research?

Exercise 1.1

Exercise 1.2

Creating an Image of Scientific Inquiry

Descriptor 1. Experience Carefully Planned in Advance

Descriptor 2. Observing Something and Trying to Explain Why It Is the Way It Is

Exercise 1.3

Descriptor 3. Updating Everyone’s Thinking in Response to More and Better Information

Doing Scientific Inquiry

Exercise 1.4

Unpacking the Terms Formulating, Testing, and Revising Hypotheses

Exercise 1.5

Exercise 1.6

Learning from Doing Scientific Inquiry

Part II. Why Do Educators Do Research?

Exercise 1.7

Part III. Conducting Research as a Practice of Failing Productively

Exercise 1.8

Exercise 1.9