what is important of research in our daily lives

Jacks Of Science

Simple Answers to Scientific Questions

Importance Of Research In Daily Life

Whether we are students, professionals, or stay-at-home parents, we all need to do research on a daily basis.

The reason?

Research helps us make informed decisions.

It allows us to learn about new things, and it teaches us how to think critically.

There is an importance of research in daily life.

Let’s discuss the importance of research in our daily lives and how it can help us achieve our goals!

6 ways research plays an important role in our daily lives.

• It leads to new discoveries and innovations that improve our lives. Many of the technologies we rely on today are the result of research in fields like medicine, computer science, engineering, etc. Things like smartphones, wifi, GPS, and medical treatments were made possible by research.
• It informs policy making. Research provides data and evidence that allows policymakers to make more informed decisions on issues that impact society, whether it’s related to health, education, the economy, or other areas. Research gives insights into problems.
• It spreads knowledge and awareness. The research contributes new information and facts to various fields and disciplines. The sharing of research educates people on new topics, ideas, social issues, etc. It provides context for understanding the world.
• It drives progress and change. Research challenges existing notions, tests new theories and hypotheses, and pushes boundaries of what’s known. Pushing the frontiers of knowledge through research is key for advancement. Even when research invalidates ideas, it leads to progress.
• It develops critical thinking skills. The research process itself – asking questions, collecting data, analyzing results, drawing conclusions – builds logic, problem-solving, and cognitive skills that benefit individuals in their professional and personal lives.
• It fuels innovation and the economy. Research leads to the development of new products and services that create jobs and improve productivity in the marketplace. Private sector research drives economic growth.

So while not always visible, research underlies much of our technological, social, economic, and human progress. It’s a building block for society.

Conducting quality research and using it to maximum benefit is key.

Research is important in everyday life because it allows us to make informed decisions about the things that matter most to us.

Whether we’re researching a new car before making a purchase, studying for an important test, or looking into different treatment options for a health issue, research allows us to get the facts and make the best choices for ourselves and our families.

• In today’s world, there’s so much information available at our fingertips, and research is more accessible than ever.
• The internet has made it possible for anyone with an interest in doing research to access vast amounts of information in a short amount of time.

This is both a blessing and a curse; while it’s great that we have so much information available to us, it can be overwhelming to try to sort through everything and find the most reliable sources.

What is the importance of research in our daily life?

Research is essential to our daily lives.

• It helps us to make informed decisions about everything from the food we eat to the medicines we take.
• It also allows us to better understand the world around us and find solutions to problems.

In short, research is essential for our health, safety, and well-being. Without it, we would be living in a world of ignorance and misinformation.

What is the importance of research in our daily lives as a student?

As a student, research plays an important role in our daily life. It helps us to gain knowledge and understanding of the world around us.

• It also allows us to develop new skills and perspectives.
• In addition, research helps us to innovate and create new things. 
• Research is essential for students because it helps us to learn about the world around us. Without research, we would be limited to our own personal experiences and observations.
• Research allows us to go beyond our personal bubble and explore new ideas and concepts.
• It also gives us the opportunity to develop new skills and perspectives. 
• In addition, research is important because it helps us to innovate and create new things. When we conduct research , we are constantly learning new information that can be used to create something new.

This could be anything from a new product or service to a new way of doing things.

Research is essential for students because it allows us to be innovative and create new things that can make a difference in the world.

Consequently, while each person’s daily life routine might differ based on their unique circumstances, the role that research plays in our lives as students is an integral one nonetheless.

Different though our routines might be, the value of research in our lives shines through brightly regardless.  And that importance cannot be overstated .

How does research affect your daily life?

Every day, we benefit from the countless hours of research that have been conducted by scientists and scholars around the world.

• From the moment we wake up in the morning to the time we go to bed at night, we rely on research to improve our lives in a variety of ways.
• For instance, many of the items we use every day, such as our phones and laptops, are the result of years of research and development.
• And when we see a news story about a new medical breakthrough or a natural disaster, it is often the result of research that has been conducted over a long period of time.

In short, research affects our daily lives in countless ways, both big and small. Without it, we would be living in a very different world.

What are the purposes of research?

The word “research” is used in a variety of ways. In its broadest sense, research includes any gathering of data, information, and facts for the advancement of knowledge.

Whether you are looking for a new recipe or trying to find a cure for cancer, the process of research is the same.

You start with a question or an area of interest and then use different sources to find information that will help you answer that question or learn more about that topic.

“The purpose of research is to find answers to questions, solve problems, or develop new knowledge.”

It is an essential tool in business , education, science, and many other fields. By conducting research, we can learn about the world around us and make it a better place.

How to do effective research 

Research is a process of uncovering facts and information about a subject.

It is usually done when preparing for an assignment or project and can be either primary research, which involves collecting data yourself, or secondary research, which involves finding existing data.

Regardless of the type of research you do, there are some effective strategies that will help you get the most out of your efforts:

• First, start by clearly defining your topic and what you hope to learn. This will help you to focus your search and find relevant information more quickly.
• Once you know what you’re looking for, try using keyword searches to find websites, articles, and other resources that are relevant to your topic.
• When evaluating each source, be sure to consider its reliability and biases.
• Finally, take good notes as you read, and make sure to keep track of where each piece of information came from so that you can easily cite it later.

By following these steps, you can ensure that your research is both thorough and accurate.

How to use research to achieve your goals.

Achieving your goals requires careful planning and a lot of hard work.

But even the best-laid plans can sometimes go awry.

That’s where research comes in.

By taking the time to do your homework, you can increase your chances of success while also learning more about your topic of interest.

When it comes to goal-setting, research can help you to identify realistic targets and develop a roadmap for achieving them.

It can also provide valuable insights into potential obstacles and how to overcome them.

In short, research is an essential tool for anyone who wants to achieve their goals.

So if you’re serious about reaching your target, be sure to do your homework first.

So the next time you are faced with a decision, don’t forget to do your research!

It could very well be the most important thing you do all day.

Jacks of Science sources the most authoritative, trustworthy, and highly recognized institutions for our article research. Learn more about our Editorial Teams process and diligence in verifying the accuracy of every article we publish.

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. 

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. 

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.

Related Articles:

• 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

How does research impact your everyday life?

“Research is to see what everybody else has seen, and to think what nobody else has thought.” – Albert Szent-Gyorgyi

What would the modern world look like without the bedrock of research?

First and foremost – without research, there’s no way you’d possibly be reading this right now, as the Internet was pioneered and developed (via a whole heap of exhaustive research…) by the European Organization for Nuclear Research , or CERN, the same association that produced the Large Hadron Collider.

Without research, we’d likely also be utterly defenceless to the brutal forces of nature. For example, without meteorology, we’d be unable to predict the path of violent storms, hurricanes and tornadoes, while a lack of volcanology research would leave a huge proportion of the world susceptible to the destruction of volcanic eruptions.

And it doesn’t end there.

Medical technology and discovery would be non-existent – no MRi , no anaesthetic, no birth control, no X-Ray machine, no insulin, no IVF, no penicillin, no germ theory, no DNA, and no smallpox vaccination – which, by the way would have wiped out one out of every nine babies had Jenner not researched and found a cure.

Source: University of Surrey

So not only is research an invaluable tool for building on crucial knowledge, it’s also the most reliable way we can begin to understand the complexities of various issues; to maintain our integrity as we disprove lies and uphold important truths; to serve as the seed for analysing convoluted sets of data; as well as to serve as ‘nourishment’, or exercise for the mind.

“…Aside from the pure pursuit of knowledge for its own sake, research is linked to problem solving,” John Armstrong, a respected global higher education and research professional, writes for The Conversation. “What this means is the solving of other people’s problems. That is, what other people experience as problems.

“It starts with a tenderness and ambition that is directed at the needs of others – as they recognise and acknowledge those needs,” he continues. “This is, in effect, entry into a market place. Much research, of course, is conducted in precisely this way beyond the walls of the academy.”

Ultimately, when we begin to look at research for what it truly is – a catalyst for solving complex issues – we begin to understand the impact it truly has on our everyday lives. The University of Surrey , set just a 10 minute walk from the centre of Guildford – ranked the 8 th best place to live in the UK in the Halifax Quality of Life Survey – is a prime example of a university producing high-impact research for the benefit of our global society.

Surrey’s experienced research team found that pollution levels inside cars were found to be up to 40 percent higher while sitting in queues, or at red lights, when compared to free-flowing traffic conditions. And with the World Health Organisation (WHO) placing outdoor air pollution among the top 10 health risks currently facing humans, linking to seven million premature deaths each year, Surrey took on the research challenge of finding an effective solution…

…And boy, did they get the results!

“Where possible and the weather conditional allowing, it is one of the best ways to limit your exposure by keeping windows shut, fans turned off and to try and increase the distance between you and the car in front while at traffic jams or stationary at traffic lights,” says Dr Prashant Kumar, Senior Author of the study. “If the fan or heater needs to be on, the best setting would be to have the air re-circulating within the car without drawing air from outdoors.”

Researchers actually found that closed windows or re-circulated air can reduce in-car pollutants by as much as 76 percent, highlighting how Surrey’s research outcomes could bring a wealth of invaluable global benefits.

As further testament to Surrey’s impactful research success, a study that uncovered high levels of Vitamin D inadequacy among UK adolescents has been published in the American Journal of Clinical Nutrition , and has now been used to inform crucial national guidance from Public Health England.

“The research has found that adolescence, the time when bone growth is most important in laying down the foundations for later life, is a time when Vitamin D levels are inadequate,” says Dr Taryn Smith, Lead Author of the study. The study forms part of a four-year, EU-funded project, ODIN, which aims to investigate safe and effective ways of boosting Vitamin D intake through food fortification and bio-fortification.

“The ODIN project is investigating ways of improving Vitamin D intake through diet,” continues Dr Smith, “and since it is difficult to obtain Vitamin D intakes of over 10ug/day from food sources alone, it is looking at ways of fortifying our food to improve the Vitamin D levels of the UK population as a whole.”

But the impact of Surrey’s research is broad and all-encompassing, with on-going projects into things like radiotherapy, dementia, blue light and human attentiveness, disaster monitoring, sustainable development, digital storytelling, and beyond. And benefits of research produced at the University of Surrey is not meant for the UK population alone; these are the issues that face us as an increasingly international and interconnected society, making research produced by world-class institutions like Surrey the tools to pave the way to bigger, brighter and healthier global future.

Find out more about studying for a postgraduate degree at Surrey by registering for one of Surrey’s Webinars .

Follow Surrey on Facebook , Twitter , Instagram , YouTube , Pinterest and LinkedIn

Feature image via Shutterstock

Liked this then you’ll love these….

The global knowledge economy

Why Study Sustainability and Environmental Sciences

Popular stories

The ultimate guide to becoming an astronaut — the requirements, how to get them, and where to study.

9 Korean language courses to take before moving to South Korea

10 lifelong skills we wish schools had taught us

The best tips to succeed in Pharmaceutical Biotechnology, according to a graduate

Science In Everyday Life: 50 Examples Showing How Science Impacts Our Daily Activities

Science plays a vital role in our daily lives, even if we don’t always realize it. From the alarm that wakes us up to the phones we scroll through before bed, advancements in science, technology, engineering, and math touch every aspect of our routines.

If you’re short on time, here’s a quick answer on examples of science in daily life: Science gives us technology like smartphones, WiFi, microwaves, and virtual assistants . It brings us medical treatments, weather forecasts, and green energy solutions.

Fields like chemistry, biology, and physics explain the world around us and advancements that enhance how we live.

This comprehensive guide provides over 50 examples demonstrating the many amazing ways science impacts our lives. We’ll cover common technologies, healthcare innovations, environmental applications, and insights science provides into the world around us.

Read on to gain appreciation for just how integral STEM is to our modern lives.

Technology Innovations from Science

Smartphones and wifi.

Smartphones have become an integral part of our lives, and we can thank science for their existence. These devices combine various technologies, such as wireless communication, touchscreen displays, and powerful processors, all made possible through scientific advancements.

With the advent of WiFi technology, we can now connect our smartphones to the internet seamlessly, allowing us to access information, communicate with others, and stay connected wherever we go. According to a report by Statista, there are over 3.8 billion smartphone users worldwide, highlighting the widespread impact of this technology.

Virtual Assistants and AI

Virtual assistants, like Siri, Alexa, and Google Assistant, have become an integral part of our daily lives. These AI-powered technologies are the result of extensive research and development in the field of artificial intelligence.

They can perform a wide range of tasks, from answering questions and setting reminders to controlling smart home devices. Virtual assistants have revolutionized the way we interact with technology and have made our lives more convenient.

According to a study by Pew Research Center, around 46% of Americans use voice assistants, showcasing the widespread adoption of this technology.

Streaming Entertainment

Gone are the days when we had to wait for our favorite TV shows or movies to air on traditional television networks. Thanks to scientific advancements, we now have streaming platforms like Netflix, Hulu, and Amazon Prime Video that allow us to enjoy a vast library of entertainment content on demand.

Streaming services rely on technologies like high-speed internet connections and video compression algorithms, which have made it possible to deliver high-quality content to our devices. According to a report by Conviva, global streaming hours increased by 57% in 2020, highlighting the growing popularity of streaming entertainment.

Kitchen Appliances

Science has also revolutionized our kitchens with innovative appliances that make cooking and food preparation easier and more efficient. From microwave ovens and induction cooktops to smart refrigerators and programmable coffee makers, these appliances utilize scientific principles to enhance our culinary experiences.

For example, microwave ovens use electromagnetic waves to heat food quickly, while induction cooktops use magnetic fields to generate heat directly in the cookware. These advancements have saved us time and energy in the kitchen, allowing us to focus on creating delicious meals.

Healthcare and Medicine

Medical treatments and drugs.

Science plays a crucial role in the development of medical treatments and drugs. Through extensive research and experimentation, scientists are able to discover new medications and therapies that help treat diseases and improve the quality of life for patients.

From antibiotics to cancer-fighting drugs, science has revolutionized the field of medicine. For instance, in recent years, breakthroughs in immunotherapy have provided hope for patients with previously untreatable cancers, offering them a chance at a longer and healthier life.

Medical Imaging and Scans

The advancement of medical imaging technology has greatly contributed to the field of healthcare. X-rays, CT scans, MRIs, and ultrasounds are all examples of medical imaging techniques that allow doctors to visualize the internal structures of the body without invasive procedures.

These imaging tools aid in the diagnosis and monitoring of various conditions, such as broken bones, tumors, and organ abnormalities. With the help of these technologies, doctors can make more accurate and timely diagnoses, leading to better treatment outcomes for patients.

Prosthetics and Implants

Science has also revolutionized the field of prosthetics and implants, providing individuals with enhanced mobility and improved quality of life. With advancements in materials science and robotics, prosthetic limbs have become increasingly sophisticated, allowing amputees to regain functionality and perform daily activities with greater ease.

Additionally, advancements in medical implants, such as pacemakers and artificial joints, have significantly improved the lives of individuals with chronic conditions, enabling them to live longer and more fulfilling lives.

Genetic Testing

Genetic testing is another area where science has had a significant impact on healthcare. With advancements in DNA sequencing technology, scientists are now able to analyze an individual’s genetic makeup and identify potential genetic disorders or predispositions to certain diseases.

This information can be used for early detection and prevention, allowing individuals to make informed decisions about their health. Genetic testing has also paved the way for personalized medicine, where treatments can be tailored to an individual’s specific genetic profile, leading to more effective and targeted therapies.

Energy and Environment

Renewable energy.

Renewable energy plays a crucial role in reducing our carbon footprint and preserving the environment. Solar power, for example, harnesses the energy from the sun and converts it into electricity, providing a sustainable and clean alternative to traditional fossil fuels.

Wind power is another example, where the kinetic energy of the wind is converted into electricity through wind turbines. According to the International Renewable Energy Agency (IRENA), renewable energy accounted for 26% of global electricity generation in 2018, and this number is expected to rise significantly in the coming years.

Harnessing the power of renewable energy sources not only reduces greenhouse gas emissions but also leads to economic growth and job creation in the renewable energy sector.

Water Filtration and Conservation

Science has greatly contributed to improving water filtration systems and promoting water conservation. Advanced technologies such as reverse osmosis and ultraviolet (UV) disinfection are used to remove impurities and pathogens from water, making it safe for consumption.

These filtration systems are essential in areas where access to clean drinking water is limited. Additionally, scientific research has led to the development of water-saving devices and techniques, such as low-flow showerheads and rainwater harvesting systems.

These innovations help conserve water resources and reduce water wastage, ultimately benefiting both the environment and our daily lives.

Weather Forecasting

Weather forecasting relies heavily on scientific advancements to accurately predict and analyze weather patterns. Meteorologists use a variety of tools and technologies, including satellites, radar systems, and computer models, to collect data and make predictions about future weather conditions.

By understanding atmospheric phenomena and analyzing historical data, scientists can provide crucial information regarding upcoming storms, hurricanes, and other weather events. Accurate weather forecasts not only help us plan our daily activities but also play a vital role in disaster preparedness and mitigation efforts, potentially saving lives and minimizing damage.

Recycling and Waste Management

In today’s world, proper waste management and recycling have become essential for the health of our environment. Science has played a significant role in developing efficient recycling processes and waste management systems.

Recycling helps reduce the amount of waste sent to landfills and conserves valuable resources. Through various scientific methods, materials such as paper, plastic, glass, and metal can be recycled and used for the production of new products.

Furthermore, advancements in waste management technologies, such as waste-to-energy systems, enable the conversion of waste materials into renewable energy sources. These innovations not only reduce the environmental impact of waste but also contribute to a more sustainable and circular economy.

Science continues to drive innovations and advancements in the energy and environmental sectors. By embracing renewable energy, implementing efficient water filtration and conservation methods, improving weather forecasting accuracy, and promoting recycling and waste management, we can create a more sustainable and environmentally friendly future.

Transportation Innovations

Aircraft technology.

Aircraft technology has come a long way since the Wright brothers’ first flight. Today, we have advanced and sophisticated airplanes that allow us to travel to any corner of the world in a matter of hours.

From the use of composite materials to improve fuel efficiency, to the development of quieter engines and advanced navigation systems, science has played a crucial role in revolutionizing air travel. The aerodynamic design of modern airplanes allows them to achieve incredible speeds while maintaining stability and safety.

This not only makes air travel more convenient for passengers but also reduces the environmental impact of aviation.

Automotive Engineering

The field of automotive engineering has witnessed tremendous advancements, making our cars safer, more efficient, and more comfortable. Science has enabled the development of innovative safety features such as airbags, ABS brakes, and collision avoidance systems, which have significantly reduced the number of accidents and saved countless lives.

The use of lightweight materials and aerodynamic designs has made cars more fuel-efficient, reducing greenhouse gas emissions. Additionally, the integration of GPS technology and smart infotainment systems has made navigation and entertainment more convenient for drivers and passengers alike.

Traffic Optimization Systems

With the increasing number of vehicles on the road, traffic congestion has become a major issue in many cities around the world. Science has played a vital role in developing traffic optimization systems that help manage and reduce congestion.

These systems use advanced algorithms and real-time data to analyze traffic patterns and suggest the most efficient routes for drivers. By optimizing traffic flow, these systems not only save time for commuters but also reduce fuel consumption and air pollution.

Examples of such systems include smart traffic lights, intelligent transportation systems, and traffic management apps.

Supply Chain Logistics

Supply chain logistics involves the management and coordination of the flow of goods and services from the point of origin to the point of consumption. Science has revolutionized this field by introducing innovative technologies and processes that improve efficiency and reduce costs.

For example, the use of barcode scanning, RFID tags, and GPS tracking has made inventory management more accurate and streamlined. Advanced analytics and predictive modeling help optimize routing and scheduling, ensuring timely delivery while minimizing transportation costs.

These innovations have transformed the way goods are transported, making supply chains more efficient and responsive to customer demands.

Insights into Our World

Science plays a fundamental role in our daily lives, often in ways we may not even realize. From the stars in the sky to the products we use, science provides us with valuable insights and understanding. Let’s explore some examples of how science impacts our everyday activities.

Astronomy and Space Science

Have you ever looked up at the night sky and marveled at the stars? Astronomy, the study of celestial objects and phenomena, helps us understand the vastness of the universe. Through telescopes and satellites, scientists have made groundbreaking discoveries about galaxies, planets, and even the origins of the universe itself.

Websites like NASA offer a wealth of information and breathtaking images that bring the wonders of space closer to us.

Physics Principles at Work

Physics is the study of matter and energy, and its principles can be found in many aspects of our daily lives. For example, the laws of motion explain why objects fall to the ground, why vehicles move, and why we can ride a bicycle.

Understanding these principles allows us to design safer cars, build sturdy bridges, and even enjoy thrilling roller coaster rides. Physics is not just for scientists in labs; it’s all around us!

Earth Sciences – Climate, Seismology

Earth sciences, such as climatology and seismology, provide us with valuable knowledge about our planet. Climate science helps us understand the changes happening in our environment and the impact of human activities on the Earth’s climate.

Seismology, the study of earthquakes, allows us to monitor and predict seismic activity, helping to save lives and minimize damage. Websites like climate.gov and USGS offer comprehensive information on these topics.

Chemistry in Everyday Products

Chemistry is present in countless products we use every day, from cleaning supplies to personal care items. For instance, the chemical reactions that occur in batteries power our smartphones and other electronic devices.

Additionally, the development of new materials and pharmaceuticals relies heavily on chemical research. Understanding the principles of chemistry allows us to create safer and more efficient products. Websites like American Chemical Society provide valuable resources on the role of chemistry in our daily lives.

Science is an integral part of our lives, providing us with knowledge and improving our understanding of the world around us. Whether it’s exploring the mysteries of space, harnessing the power of physics, studying our planet’s climate, or utilizing chemistry in everyday products, science impacts our daily activities in profound ways.

As this extensive list of examples shows, science fundamentally shapes our daily lives in modern society. Cutting-edge innovations that enhance how we live, work, communicate, travel, stay healthy, and understand the world all stem from scientific discovery.

Fields like physics, chemistry, biology, astronomy, and engineering create astounding technologies, life-saving medications, and solutions for sustainability. They also unlock deeper insights into our own bodies, the environment, and the universe around us.

So whether you’re video chatting on your phone, cooking dinner, driving your car, or just breathing – you have science to thank! Our modern world simply would not function without the dedicated work of scientists pushing boundaries every day.

Similar Posts

The Science Of Human Behavior: An In-Depth Look

Understanding why people think, feel, and act as they do has long been a subject of fascination and study. Across history, philosophers, researchers, and scientists have sought to make sense of the mysteries of human nature. But what specific field focuses on analyzing and explaining human behavior using scientific methods? If you’re short on time,…

An Overview Of The Core Concepts And Skills Learned In A Computer Science Education

Computer science encompasses a broad range of subjects and disciplines focused on computing technologies and their applications. If you’re short on time, here’s a quick answer to your question: In a computer science education, students learn programming, algorithms, data structures, computer architecture, systems design, cybersecurity, artificial intelligence, and more while building critical thinking and problem-solving…

Careers That Don’T Require Math Or Science

If complex math and science equations make your head spin, you’re not alone. Fortunately, there are plenty of great careers out there that allow you to play to your strengths while avoiding advanced technical coursework. If you’re short on time, here’s a quick answer to your question: Many careers in business, communications, the arts and…

How To Study Effectively For A Computer Science Exam

Computer science exams test mastery of programming languages, algorithms, data structures, and other complex technical concepts. With so much material to cover, sufficient preparation is key to succeed on CS exams. If you’re short on time, here’s a quick answer: Start studying 2-3 weeks before the CS exam, focus on thoroughly understanding course material versus…

Does The Pope Have A Science Degree? Examining The Education Of The Pontiff

As the head of the Catholic Church, the Pope wields immense influence over billions of followers worldwide. Naturally, many are curious about the background and education of whoever holds this august office. If you’re short on time, here’s a quick answer to your question: While Pope Francis studied chemistry and psychology in college, he does…

Can You Take Ap Computer Science A With No Experience?

In today’s tech-driven world, computer science skills are highly valued across industries. This has led many high school students without prior coding experience to consider taking AP Computer Science A. If you’re short on time, here’s a quick answer to your question: Yes, you can take AP Computer Science A with no prior experience. However,…

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

Understanding Science

How science REALLY works...

• Understanding Science 101
• Scientific findings frequently benefit society through technological and other innovations.
• Technological innovations may lead to new scientific breakthroughs.
• Some scientists are motivated by potential applications of their research.

Benefits of science

The process of science is a way of building knowledge about the universe — constructing new ideas that illuminate the world around us. Those ideas are inherently tentative, but as they cycle through the process of science again and again and are tested and retested in different ways, we become increasingly confident in them. Furthermore, through this same iterative process, ideas are modified, expanded, and combined into more powerful explanations. For example, a few observations about inheritance patterns in garden peas can — over many years and through the work of many different scientists — be built into the broad understanding of genetics offered by science today. So although the process of science is iterative, ideas do not churn through it repetitively. Instead, the cycle actively serves to construct and integrate scientific knowledge.

And that knowledge is useful for all sorts of things: designing bridges, slowing climate change, and prompting frequent hand washing during flu season. Scientific knowledge allows us to develop new technologies , solve practical problems, and make informed decisions — both individually and collectively. Because its products are so useful, the process of science is intertwined with those applications:

• New scientific knowledge may lead to new applications. For example, the discovery of the structure of DNA was a fundamental breakthrough in biology. It formed the underpinnings of research that would ultimately lead to a wide variety of practical applications, including DNA fingerprinting, genetically engineered crops, and tests for genetic diseases.
• New technological advances may lead to new scientific discoveries. For example, developing DNA copying and sequencing technologies has led to important breakthroughs in many areas of biology, especially in the reconstruction of the evolutionary relationships among organisms.
• Potential applications may motivate scientific investigations. For example, the possibility of engineering microorganisms to cheaply produce drugs for diseases like malaria motivates many researchers in the field to continue their studies of microbe genetics.

The process of science and you

This flowchart represents the process of formal science, but in fact, many aspects of this process are relevant to everyone and can be used in your everyday life. Sure, some elements of the process really only apply to formal science (e.g., publication, feedback from the scientific community), but others are widely applicable to everyday situations (e.g., asking questions, gathering evidence, solving practical problems). Understanding the process of science can help anyone develop a scientific outlook on life.

• Take a sidetrip

To find out how to develop a scientific outlook, visit  A scientific approach to life: A science toolkit .

• Science in action
• Teaching resources

Scientific results regularly make their way into our everyday lives. Follow scientific ideas from lab bench to application:

• The structure of DNA: Cooperation and competition
• Ozone depletion: Uncovering the hidden hazard of hairspray

Want to learn even more about the relationship between science and its applications? Jump ahead to these units:

• Science and society
• What has science done for you lately?
• Use our  web interactive  to help students document and reflect on the process of science.
• Learn strategies for building lessons and activities around the Science Flowchart: Grades 3-5 Grades 6-8 Grades 9-12 Grades 13-16
• Find lesson plans for introducing the Science Flowchart to your students in: Grades 3-5 Grades 6-8 Grades 9-16
• Get  graphics and pdfs of the Science Flowchart  to use in your classroom. Translations are available in Spanish, French, Japanese, and Swahili.

Copycats in science: The role of replication

Science at multiple levels

Subscribe to our newsletter

• The science flowchart
• Science stories
• Grade-level teaching guides
• Teaching resource database
• Journaling tool
• Misconceptions

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.

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

   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 coming to an agreement, and it could be quite some time before a consensus emerges. In other cases, rapidly developing technology is improving our ability to measure things, and changing our earlier understanding of how the mind works.

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?

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

   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 observations lead to more ideas that are tested against the real world, and so on. In this sense, the scientific process is circular. We continually test and revise theories based on new evidence.

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.

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).

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.

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

10 Practical Uses of Science in Our Daily Life

• Kristina C.
• September 2024
• 17 minutes read
• Correction policy

Science is a fascinating field that impacts our daily lives in countless ways. From the moment we wake up to the time we go to bed, science plays a crucial role in shaping our experiences. It is responsible for the technological advancements and innovations that surround us, making our lives easier, safer, and more enjoyable.

In our daily lives, science is used in various ways. It allows us to communicate instantly with loved ones across the globe, thanks to the wonders of technology. Science is behind the development of medicines and vaccines that help us stay healthy and fight diseases. It enables us to travel faster and more efficiently, whether by car, train, or airplane.

Moreover, science helps us understand and appreciate the world around us. It explains the natural phenomena we witness, such as the changing seasons or the movement of the stars. Science also fuels our curiosity, pushing us to explore the depths of the ocean or the vastness of outer space.

In essence, science is a constant companion in our daily lives, enhancing our experiences and providing us with endless possibilities. It is the driving force behind progress and innovation, making our lives more exciting and fulfilling. So the next time you marvel at the wonders of modern technology or experience the wonders of nature, remember that science is at the heart of it all.

People also ask

Science importance & use in our daily life - youtube (video).

Health and Medicine

Health and medicine are areas where the daily use of science is invaluable. From diagnosing illnesses to developing new treatments, science plays a vital role in improving our well-being. Medical advancements have led to the discovery of life-saving drugs, the development of surgical techniques, and the implementation of preventative measures.

In addition to treating diseases, science also helps us understand the human body better, aiding in the prevention of illnesses and the maintenance of good health. It allows us to gain insights into the intricacies of our biology, enabling us to make informed decisions about our lifestyles. Science has also contributed to the creation of innovative medical technologies, such as imaging machines, prosthetics, and telemedicine, which have revolutionized healthcare delivery.

Furthermore, scientific research has paved the way for the development of vaccines, which have eradicated or significantly reduced the prevalence of deadly diseases. Science's impact on health and medicine is far-reaching, improving the quality and longevity of our lives.

Communication and Technology

Communication and technology play a crucial role in our daily lives, thanks to science. From the moment we wake up to the moment we go to bed, we are constantly surrounded by various forms of communication and technology that have become an integral part of our routines. Whether it's using our smartphones to send text messages, checking emails on our laptops, or even watching television, science has made all of these activities possible.

Not only does science enable us to communicate with others effortlessly, but it also allows us to stay connected with the world around us. Through social media platforms, we can share our thoughts and experiences with friends and family, even if they are miles away. Science has revolutionized the way we communicate by introducing video calls and instant messaging services, making it easier than ever to connect with loved ones in real-time.

Technology has also greatly improved our productivity and efficiency. With the help of science, we now have access to a multitude of devices and gadgets that simplify our daily tasks. From smart home systems that allow us to control our appliances with a single command to navigation apps that guide us to our desired destinations, science has enhanced our lives in countless ways.

Moreover, science has transformed the way we access information and gain knowledge. With just a few taps on a screen, we can find answers to our questions, explore different topics, and educate ourselves on various subjects. The internet and search engines have become our go-to sources of information, empowering us to learn and grow every day.

Science has revolutionized communication and technology, making our lives more interconnected and convenient. With advancements in science, we can stay connected with loved ones, simplify daily tasks, and access a wealth of knowledge at our fingertips. The 10 uses of science in our daily lives encompass various aspects, from communication to productivity and beyond, shaping the way we live and interact with the world.

Transportation and Travel

Science plays a crucial role in transportation and travel, impacting our daily lives in numerous ways. Firstly, advancements in science have revolutionized the way we travel, with the invention of various modes of transportation such as cars, airplanes, and trains. These innovations have made it quicker and more convenient for people to commute and explore different parts of the world.

Science has also improved the safety and efficiency of transportation systems. Through the use of advanced technologies like GPS navigation and traffic control systems, science has helped in reducing accidents and congestion on roads, ensuring smoother and faster travel experiences.

Furthermore, science has contributed to the development of fuel-efficient engines and alternative energy sources, enabling us to reduce our carbon footprint and promote sustainable travel. Electric vehicles and hybrid cars are prime examples of how science is transforming the transportation industry to be more environmentally friendly.

In the realm of travel, science has provided us with tools and resources to explore and understand the world around us. From global positioning systems (GPS) to weather forecasting technologies, science has made it easier for travelers to navigate unfamiliar territories and plan their journeys effectively.

Science plays a vital role in shaping the transportation and travel sector. Through constant advancements and innovations, it has revolutionized the way we commute, improved safety measures, and promoted sustainability. Science continues to drive progress in this field, making travel more accessible, efficient, and enjoyable for everyone.

"Science is the key to unlocking the doors of the future and understanding the world we live in." - Neil deGrasse Tyson

Energy and Environment

Energy and the environment are closely interconnected, with science playing a crucial role in both areas. Science provides us with the knowledge and tools to understand and address the environmental challenges we face, while also helping us harness and utilize energy efficiently.

• Renewable Energy: Science has enabled us to tap into renewable sources of energy such as solar, wind, and hydroelectric power. These sustainable alternatives help reduce our dependence on fossil fuels, decrease greenhouse gas emissions, and mitigate climate change.
• Energy Conservation: Through scientific research, we have gained a deeper understanding of energy conservation techniques. This knowledge has led to the development of energy-efficient appliances, smart grids, and building design strategies that reduce energy consumption and promote sustainability.
• Environmental Monitoring: Science plays a vital role in monitoring and assessing the health of our environment. Scientific techniques and technologies, such as remote sensing and data analysis, allow us to study air and water quality, biodiversity, and the impacts of human activities on ecosystems. This information is crucial for making informed decisions and implementing effective environmental policies.
• Waste Management: Science helps us manage and minimize waste effectively. Scientific advancements have led to the development of recycling technologies, waste treatment methods, and strategies for reducing pollution. By applying scientific knowledge, we can reduce the environmental impact of waste and move towards a more sustainable approach to resource management.

Science is instrumental in addressing the energy and environmental challenges we face. It empowers us to adopt sustainable practices, develop cleaner energy sources, and protect our environment for future generations. By embracing scientific advancements, we can create a healthier, more sustainable world.

💡 Tip: Conserving energy is essential for both our environment and our wallets. Simple changes like turning off lights when not in use, using energy-efficient appliances, and reducing water consumption can make a significant impact. By being mindful of our energy usage, we can contribute to a more sustainable future.

Agriculture and Food

Science plays a crucial role in agriculture and food production, impacting nearly every aspect of our daily lives. Through scientific advancements, we have been able to increase crop yields, improve food quality, and develop sustainable farming practices.

One of the key uses of science in agriculture is the development of genetically modified organisms (GMOs). Through genetic engineering, scientists have been able to enhance crop traits such as pest resistance and drought tolerance, resulting in higher yields and better crop productivity. This has been essential in feeding our growing global population.

Science also helps in the development of fertilizers and pesticides. Through scientific research, we are able to create fertilizers that provide the necessary nutrients for plant growth, improving crop yields. Similarly, pesticides help control pests and diseases, protecting crops and ensuring food security.

In addition, science plays a crucial role in soil management. Through soil testing and analysis, scientists can determine the nutrient content and pH levels of the soil, allowing farmers to make informed decisions about fertilization and irrigation. This helps optimize crop growth and reduces the risk of nutrient deficiencies.

Furthermore, science has revolutionized food preservation and storage. Through techniques such as canning, freezing, and drying, we can extend the shelf life of perishable foods, reducing food waste and ensuring a stable food supply.

Science also contributes to the development of sustainable farming practices. Through research on organic farming methods, crop rotation, and integrated pest management, we can minimize the use of harmful chemicals and promote environmentally friendly farming practices.

Science plays a vital role in agriculture and food production, helping us meet the demands of a growing population while ensuring sustainable and efficient farming practices. By harnessing scientific advancements, we can continue to improve crop yields, enhance food quality, and protect our environment for future generations.

Home and Household

Science plays a crucial role in our daily lives, even within the comfort of our own homes. From the moment we wake up to the time we go to sleep, science is at work, making our lives easier and more convenient.

In the kitchen, science allows us to cook our meals efficiently and safely. The principles of chemistry and physics help us understand how heat is transferred during cooking, ensuring that our food is cooked thoroughly and evenly. Science also helps us preserve our food through refrigeration and freezing, allowing us to enjoy fresh produce and prevent food waste.

In terms of cleaning, science provides us with a range of products and tools that make household chores easier. The chemistry behind detergents and cleaning agents helps us remove stains and sanitize our homes effectively. Science also plays a role in developing efficient appliances, such as vacuum cleaners and washing machines, that save us time and energy.

In home maintenance, science enables us to understand the structural integrity of our homes. Engineering principles guide architects and builders in constructing safe and sturdy houses. Science also helps us maintain our homes by providing knowledge about plumbing, electrical systems, and insulation, ensuring our comfort and safety.

Beyond the kitchen and maintenance, science is also present in our entertainment and relaxation. From television screens and audio systems to gaming consoles and streaming services, science fuels our entertainment devices, enhancing our leisure time.

Science is intertwined with our daily lives, even within the confines of our homes. From cooking and cleaning to home maintenance and entertainment, science contributes to our well-being and convenience. By understanding and appreciating the scientific principles behind these aspects, we can fully maximize the benefits that science brings into our everyday lives.

Education and Learning

Education and learning play a crucial role in our daily lives, and science is an integral part of this process. Science provides us with the tools and knowledge to explore and understand the world around us. It helps us develop critical thinking skills, enhances our problem-solving abilities, and fosters a sense of curiosity and wonder. One of the uses of science in education and learning is through practical experiments and hands-on activities.

By conducting experiments, students can apply scientific principles and theories to real-life situations, allowing them to see the practical applications of what they are learning. This not only helps to reinforce their understanding of scientific concepts but also encourages them to think creatively and develop their own ideas.

Science also plays a vital role in technological advancements, which have revolutionized the field of education. With the help of science, we now have access to online learning platforms, educational apps, and interactive simulations that make learning more engaging and accessible. These technologies provide students with a wealth of resources and opportunities for self-directed learning, allowing them to explore different topics and personalize their educational experiences.

Furthermore, science has contributed to the development of innovative teaching methods and instructional strategies. Educators can now incorporate multimedia materials, such as videos, animations, and virtual reality, into their lessons to enhance students' understanding and engagement. These interactive and visually stimulating resources help to cater to different learning styles and make complex concepts more accessible.

Science also plays a significant role in curriculum development. By integrating scientific principles into various subjects, such as mathematics, language arts, and social studies, students can see the interconnectedness of different disciplines. This interdisciplinary approach not only helps them develop a holistic understanding of the world but also encourages them to think critically and make connections between different concepts.

In addition to these uses, science also promotes lifelong learning. By cultivating a scientific mindset, individuals become lifelong learners who are constantly seeking new knowledge and information. Science encourages us to question the world around us, explore new ideas, and seek evidence-based answers. This mindset of curiosity and inquiry extends beyond the classroom and has numerous applications in our daily lives, from making informed decisions about our health to understanding complex societal issues.

Science plays a vital role in education and learning by providing practical applications, technological advancements, innovative teaching methods, interdisciplinary approaches, and a mindset of lifelong learning. Its impact goes beyond the classroom, empowering individuals to navigate the complexities of the world and make informed decisions. By incorporating science into education, we equip students with the tools and skills they need to thrive in an ever-changing society.

Entertainment and Recreation

Entertainment and recreation play a crucial role in our daily lives, providing us with much-needed relaxation and enjoyment. Science has revolutionized these aspects of our lives, making them more diverse, accessible, and immersive than ever before.

One of the most prominent uses of science in entertainment is the development of virtual reality (VR) technology. Through VR, we can transport ourselves to various virtual worlds, experiencing everything from thrilling adventures to peaceful getaways. This technology is made possible through scientific advancements in computer graphics, optics, and human-computer interaction.

Science has also brought us innovative forms of entertainment, such as 3D movies and augmented reality (AR) games. These technologies combine scientific principles with creative storytelling, allowing us to immerse ourselves in captivating visual experiences.

Beyond virtual realms, science has enhanced traditional forms of entertainment. The development of high-definition televisions and surround sound systems has elevated our movie-watching and gaming experiences, bringing us closer to the action and enhancing our enjoyment.

In the realm of recreational activities, science has provided us with various tools and equipment that enhance our performance and safety. Sports gear, such as advanced tennis rackets and golf clubs, are designed using scientific principles to optimize our performance. Scientific research has led to the development of protective equipment like helmets and padding, ensuring our safety during physical activities.

Science has even influenced the way we enjoy music. From the invention of musical instruments to the advancements in sound recording and production, scientific principles have shaped the way we create, listen, and appreciate music.

Science has revolutionized entertainment and recreation, providing us with immersive experiences, innovative technologies, and enhanced equipment. Through scientific advancements, we can enjoy a wide range of entertainment options and engage in recreational activities safely and with optimal performance. Embrace the wonders of science and let it enrich your daily life through entertainment and recreation.

Safety and Security

Safety and security are paramount in our daily lives, and science plays a crucial role in ensuring our well-being. From the moment we wake up to the time we go to sleep, science is at work, safeguarding us in various ways. One of the key uses of science in ensuring our safety and security is through advanced surveillance systems.

These systems utilize cutting-edge technology, such as facial recognition and motion sensors, to monitor and detect any potential threats or suspicious activities. This helps in preventing crime and protecting public spaces.

Science also contributes to our safety through advancements in the field of medicine. Medical researchers and scientists work tirelessly to develop vaccines, medicines, and treatments that safeguard us from diseases and ailments. From flu shots to life-saving surgeries, science enables us to live healthier and longer lives.

Furthermore, science plays a pivotal role in enhancing transportation safety. Through the development of innovative technologies, such as anti-lock braking systems and airbags, science has significantly reduced the risk of accidents and injuries on the road. Advancements in aviation technology have made air travel safer than ever before.

In the realm of cybersecurity, science is essential in protecting our personal information and digital assets. Scientists continuously innovate and develop robust encryption algorithms and security protocols to safeguard our data from cyber threats and hacking attempts.

Science is indispensable when it comes to ensuring our safety and security in various aspects of our lives. From surveillance systems to medical breakthroughs, transportation safety, and cybersecurity, science empowers us to live in a safer and more secure world.

Research and Innovation

Research and innovation are essential components of our daily lives, contributing to advancements in science that impact our world in numerous ways. Science plays a crucial role in improving technology, healthcare, communication, transportation, and much more. Through research and innovation, scientists and inventors continuously strive to enhance our daily lives.

In the field of medicine, research and innovation have led to the development of life-saving drugs and treatments, prolonging and improving the quality of life for countless individuals. Scientists constantly explore new avenues to combat diseases, inventing innovative techniques and therapies that have revolutionized healthcare.

Moreover, research and innovation have transformed the way we communicate and access information. Through scientific advancements, we now have instant access to vast amounts of knowledge through the internet and various technological devices. This has facilitated global connectivity, allowing us to connect with people from all corners of the world.

Transportation has also greatly benefited from research and innovation. From the invention of automobiles to the development of sustainable energy sources, science has enabled us to travel faster, more efficiently, and in a more environmentally friendly manner. Research in the field of aerospace has led to the exploration of space, expanding our understanding of the universe.

Research and innovation are vital in improving our daily lives. They drive progress in various fields, including medicine, technology, communication, and transportation. Through continuous scientific exploration, we can look forward to even more advancements that will shape the future of our world. So, let's embrace research and innovation as catalysts for a brighter and more prosperous tomorrow.

Given these points

Science is not just a subject taught in schools; it is a fundamental part of our daily lives. From the moment we wake up to the moment we go to bed, science influences and improves every aspect of our existence.

Whether it's the advancements in medicine that keep us healthy, the technology that connects us with the world, or the innovations that make our lives more comfortable, science is the driving force behind it all. By understanding and appreciating the practical uses of science in our daily life, we can fully embrace the incredible achievements of human knowledge and continue to push the boundaries of what is possible.

Comments (0)

Comments are currently closed. Subscribe to get notified when comments are open.

Join now our growing comunity!

Related articles

When Science Gets Romantic: Exploring the Chemistry of Love

Why Science Challenges Belief: Uncovering the Truth Behind Skepticism

How Much Science Influences Engineering

Unveiling the Mysteries: Can Science Explain Gravity?

Science and Faith: A Harmonious Coexistence

Are Science Fiction and Fantasy the Same? Exploring the Differences and Similarities

Who is considered the Father of Science?

Exploring the Fascinating World of Science in 12th Grade

Science and Math: Unraveling the Intricate Relationship

Where Science Came From: Unraveling the Origins of Scientific Inquiry

Can Science Be Proven: Unveiling the Truth Behind Scientific Certainty

Are Science and Technology the Same? Exploring the Differences and Connections

The Importance of Research in the Advancement of Society

Thanks to the internet and other technologies, life moves at a very fast pace. We’re constantly adapting and learning new ways to do things–as well as expecting and even demanding innovation from our scientists, executives, and leaders.

Without research, our demands would go completely unanswered!

Curiosity leads to research

Research is what propels humanity forward. It’s fueled by curiosity: we get curious, ask questions, and immerse ourselves in discovering everything there is to know. Learning is thriving. Without curiosity and research, progress would slow to a halt, and our lives as we know them would be completely different.

What would happen without research?

If early civilizations hadn’t been curious about the dark sky, we wouldn’t know anything about space. Decades of research have led us to where we are today: a civilized society with the knowledge and tools to move forward.

If that research slowed to a standstill, what would happen?

We’d become ignorant and unaware. We wouldn’t understand or go forward. Without research, we couldn’t say we were close to finding the cure for cancer or find the most eco-friendly way to light up our homes and offices. We wouldn’t know that, even though bees are not our favorites, they do a job that help us all.

Without research, we could not possibly have survived as long as we have.

And there are still millions of things that have yet to be discovered: diseases to cure, waters to explore, species to discover. All of that is possible with research.

The future of research

Thankfully, schools are becoming more concerned with science and technology, and research is finding its place in the minds of today’s students. Students are eager to make discoveries, create solutions to the world’s problems, and invent the next big thing. We’re going places, one research project at a time.

How do we enable researchers to spend their time on, well, research (instead of filling out forms)? Thankfully, there’s cloud-based software to make that easier. Researchers and research administrators can find funding faster , apply for it more easily, manage their funding once they get it, meet federal and local requirements for documentation, stay in compliance if research involves humans or animals, and make sure research facilities are safe .

All of that means they’re one step closer to tomorrow’s big discoveries.

Adapted from an essay by Cali Simboli

Ready for easier research administration?

Featured resource:.

6 ways to minimize risk in research administration

Get ebook >> 

Talking about science and technology has positive impacts on research and society

Associate Professor and Canada Research Chair in Science, Health, and Technology Communication, University of Waterloo

Professor, Department of Physics and Astronomy, University of Waterloo

Dean, Faculty of Engineering, University of Waterloo

Disclosure statement

Ashley Rose Mehlenbacher works for the University of Waterloo and is the co-director of the TRuST network. She receives funding from the Canada Research Chairs program and has received funding from the Canadian Foundation for Innovation, Social Sciences and Humanities Research Council of Canada, Natural Sciences and Engineering Research Council of Canada, the Ontario Early Researcher Program, and others.

Donna Strickland and Mary Wells do not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and have disclosed no relevant affiliations beyond their academic appointment.

University of Waterloo provides funding as a founding partner of The Conversation CA.

University of Waterloo provides funding as a member of The Conversation CA-FR.

View all partners

Discussions around science and technology can become controversial, such as public conversations around climate science or gene-editing tools .

That might leave the impression that such conversations are best avoided. But it is important to have constructive conversations about scientific and technical subjects because of how they impact our lives.

Not having these conversations can lead to further division and strained relationships. Avoidance of such conversations could also have serious implications for scientific research support such as the continued development of life-saving vaccines or in deciding how we might regulate emerging technologies such as generative artificial intelligence.

Read more: Generative AI like ChatGPT reveal deep-seated systemic issues beyond the tech industry

The ancient Greeks had a term for opportune moments, or those qualitative measures of time where things just seem to be right for some action. They called these kairotic . The term kairos is a qualitative measure of time, as opposed to chronos , or linear quantitative time.

It is a kairotic moment to talk about trust — which we might think of as a very old idea but is highly important today — as we see new science emerging and technologies developing apace.

Polarizing information

The consequences of allowing issues in science and technology to be so polarized that we don’t talk about them include economic impacts , Canada falling behind in applied and basic scientific research and responsible technology development .

We need to have direct conversations about scientific research, progress, experts and expertise , and new technologies that may become critically important to society in the future .

Together, we have built a research network called TRuST at the University of Waterloo.

Our inaugural lecture series event began this conversation about trust in science, technology and health in Canada, and we hope to continue these conversations through an ongoing speaker series and collaborations with other researchers and organizations.

Our work asks the tough questions about why people do — or don’t — trust science and technology , who is found trustworthy , how trust is earned and lost and how we can have conversations about science and technology in the service of us all.

By doing so, we hope to launch conversations about these topics, not to provide definitive answers or to tell anyone what to think.

A crisis of trust?

While there appears to be a public crisis in trust, there is a good deal of complexity when we talk about concepts of trust and who is trustworthy. Trust in scientists and interest in science has remained high for a number of years, but there are some trends that raise questions about whether that is changing.

Overall, trust in medical doctors and scientists , for example, seems to have declined somewhat since the early days of the COVID-19 pandemic when trust was somewhat higher than normal.

Surveys and polls give us high-level insights, but we also know that there are issues that become controversial. We also know that how questions are asked in a survey or poll can influence the nature of responses. For instance, if we ask “do you trust scientists,” do you think about scientists generally or are you thinking of a specific scientist?

Sometimes controversy is manufactured , as in the case of climate change where the prevailing consensus among scientists was strategically downplayed. Sometimes the way we frame an issue can lead to confusion and mistrust.

Once an issue is controversial it can be polarizing and polarizing language can influence how we think and talk about issues.

And of course, social media influences how scientific knowledge is shared, distorted , “ironically reversed” , exploited and corrected — or not.

Communicating through disagreement

How do we talk to each other when we might not agree?

First, you need to have capacity, both emotionally and in terms of conversational skill, and some knowledge and interest in a topic to undertake this work.

Listening is a good place to begin, and by that we mean genuinely trying to hear and understand someone’s perspective. You might not agree, but you cannot engage their ideas if, for instance, you’re talking about if something actually happened and someone else is speculating about what happened.

This might seem like a subtle distinction, but these are the important distinctions. In the field of rhetoric , we might talk about this as a problem of stasis : you’re asking a question about if something is a fact and someone else is talking about the definition of what they have already taken to be a fact.

Listening means working hard to determine what someone else is talking about and while you can still disagree, calling out misinformation or otherwise challenging points, you should do so empathetically and respectfully. We can work towards building bridges that will productively move a conversation forward.

Built into this is a certain amount of respect for the person you’re talking to — even if you’re an expert , you need ethos which means character built upon goodwill ( eunoia ), good morals ( arete ) and good sense or reason ( phronesis ) — and also goodwill to understand their perspective.

Goodwill, however, goes both ways. If someone you are listening to does not seem to be coming to a conversation in good faith or with goodwill, it might be time to excuse yourself.

Read more: The U.S. Capitol violence could happen in Canada — here are 3 ways to prevent it

Better science, better technology

Improving science, our ethical processes for technology development and deployment and how we engage in conversations about how these efforts should shape our communities and everyday lives also requires work on the part of scientists, engineers and other experts.

Developing strategies to talk about our research methods and how science works and, critically, to listen to people’s concerns is a first step in responsibly and ethically communicating science . It is a step experts can take with family, friends and in their communities. Working to support knowledge sharing from a wide variety of experts that better reflect the range of people and experiences in our communities is also very important.

Because trust requires certain kinds of vulnerability, the trustworthiness of experts is important in science and technology.

Relationships between experts and non-experts are asymmetrical. Experts often have knowledge that others need, and others must trust that experts will provide that knowledge and do so with goodwill, good sense and good judgment in line with shared values. When this is perceived as not happening, trust can be reduced or lost.

Trust is critical to the advancement of science itself and science in the advancement of society.

• Science communication
• Scientific research
• Listen to this article
• Universites

Service Centre Senior Consultant

Director of STEM

Community member - Training Delivery and Development Committee (Volunteer part-time)

Chief Executive Officer

Head of Evidence to Action

• 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

Why is freedom important (14 reasons), international human solidarity day- importance and history, importance of food in our daily life and why its necessary, pin it on pinterest.

Research and Its Importance for Daily Life Essay

• To find inspiration for your paper and overcome writer’s block
• As a source of information (ensure proper referencing)
• As a template for you assignment

Introduction

Impact of research, qualities of effective research, role of beliefs and values.

Research plays an important role in science. This is normally done to obtain detailed knowledge about certain aspects before an invention. Scientific research involves the study of diseases and other parameters to invent medicine and vaccines. Therefore, without research, there will be no inventions and therefore a big blow to health. Essentially research fulfils purposes that are designed before the exercise. However, apart from that, research has other implications on reality and daily lives. As a result, the effects of research go beyond the purpose it is meant for. This paper aims to take an analytical look at the concept of research. The paper will begin with a detailed look at the concept of research. Thereafter, the several similarities between different aspects of research will be analyzed. The impact of research on our daily life will also be reviewed.

Research has a lot of impact on the daily functioning of life. First and foremost, research leads to a better life by producing results that can be used to make life better. Especially as far as scientific research is concerned, the invention of vaccines and medicines makes diseases to be less of a threat to society (Calderon & Slavin 2001). Therefore, through the process of research, various methods of handling life’s problems and making the world a better place to live in are facilitated. Secondly, the very process of research affects society in several ways. The impact of the process of research has two dimensions.

The first part is the negative part in which the process of research has certain consequences for society. Unethical practices harm society. Since research is done on people in society, the practices adopted by the researchers have a lot of impacts. Scientific research has left some people with serious illnesses and injuries sometimes; it is like experimenting with people’s life. However, the process of research also has positive effects on society (McGill 1981). This is mainly because of employment opportunities, awareness and education. Research offers vast opportunities to the members of society to learn and obtain understanding about certain issues. At the same time, the participants of the research are remunerated making them earn a living from the same.

Several factors denote effective and valid research. To conduct valid or effective research, therefore, several considerations must be in place. First is the aspect of ethics, for research to be valid it must be conducted ethically. This involves the practices adopted for the research (Cresswell 2003). If the research involves risks, this must be communicated to the participants in advance. At the same time plans must be in place to compensate all those that will be affected in the course of the research. The disbursing of information is necessary before the research. This is important to take care of deception which is rampant in research. In general, proper preparation and education of the participants is the key to successful research. Another crucial requirement is the availability of resources for research.

Several forms of research involve a different processes. As a result, not all forms of research involve vigour. For instance, scientific research on diseases is more demanding than research on recreational issues. This is due to the context of the studies and the parameters involved. For instance, scientific research involves several processes and procedures which tend to take more resources. Recreational issues, on the other hand, are less involved due to the nature of the subject. The research can therefore be conducted with much ease.

Beliefs and values have a lot of impact on the process of research. People’s beliefs, therefore, influence the outcome and process of research. This is due to the relevance that beliefs and values have on people’s perception and philosophy of life. For instance, certain topics are considered sacred and secret in certain societies (Bryant 2005). Their beliefs don’t allow them to discuss certain things. Therefore in the process of collecting information from such people, it becomes very difficult to deal with them. People’s values also play a huge role. Some people are flexible in certain areas than others. Therefore, when conducting research one must understand the values of all participants. This is because their values determine how they approach certain issues. Religion plays a great role in determining the beliefs and values of people.

Research is part and parcel of life, in fact without research life will not be as it is. To live better life research is necessary; this is because research leads to innovation and invention. As far as science is concerned research leads to the invention of vaccines and drugs. Other areas of research also lead to a better understanding of the concepts involved. However, it is not only the results of research that benefit society but also the process of research. Some several opportunities and benefits that come with the process of research. As a result, the role of research in society goes beyond its real purpose. For research to be effective and valid several factors must be considered. Chief among them is the aspect of ethics. Different forms of research involve different forms of approaches. As a result, certain forms of research are more demanding than others. The influence of values and beliefs is notable as far as research is concerned. The paper has discussed the concept of research in detail. The process and impact of research have also been discussed.

Bryant, M. (2005). Managing an Effective and Ethical Research Project . London: Berrett-Koehler Publishers.

Calderon, M. & Slavin, R. (2001). Effective programs for Latino students. New York: Routledge.

Cresswell, J. (2003). Research design: qualitative, quantitative, and mixed-method approaches. New York: SAGE.

McGill, N. (1981). Effective research: a handbook for health planners. Washington: Institute for Health Planning.

• Market Condition Survey and Grading
• School Counseling Study: Data Analysis
• Do Vaccines Cause Autism?
• The Companies Investing Heavily in Vaccine
• The Stages of Production of the H1N1 Influenza Vaccine
• Dynamic Nature of Discovery: Crystal Skulls
• The Indispensability Argument Putting Forward by Quine and Putnam
• Pressure in Work, University and Life
• Questionnaire for Character Education Program Evaluation
• Research Question Types: Advantages and Disadvantages
• Chicago (A-D)
• Chicago (N-B)

IvyPanda. (2021, December 29). Research and Its Importance for Daily Life. https://ivypanda.com/essays/research-and-its-importance-for-daily-life/

"Research and Its Importance for Daily Life." IvyPanda , 29 Dec. 2021, ivypanda.com/essays/research-and-its-importance-for-daily-life/.

IvyPanda . (2021) 'Research and Its Importance for Daily Life'. 29 December.

IvyPanda . 2021. "Research and Its Importance for Daily Life." December 29, 2021. https://ivypanda.com/essays/research-and-its-importance-for-daily-life/.

1. IvyPanda . "Research and Its Importance for Daily Life." December 29, 2021. https://ivypanda.com/essays/research-and-its-importance-for-daily-life/.

Bibliography

IvyPanda . "Research and Its Importance for Daily Life." December 29, 2021. https://ivypanda.com/essays/research-and-its-importance-for-daily-life/.

What Is Research, and Why Do People Do It?

• Open Access
• First Online: 03 December 2022

Cite this chapter

You have full access to this open access chapter

• 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.

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.

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.

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. ).

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.

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.

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

© 2023 The Author(s)

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

The university of tulsa Online Blog

Trending topics in the tu online community

Nursing Research: What It Is and Why It Matters

When people think about medical research, they often think about cutting-edge surgical procedures and revolutionary new medications. As important as those advancements are, another type of research is just as vital: nursing research.

This type of research informs and improves nursing practice. In many cases, it’s focused on improving patient care. Experienced nurses who have advanced nursing degrees and training in research design typically conduct this research.

Nurse research can explore any number of topics, from symptomology to patient diet. However, no matter the focus of a research project, nurse research can improve health care in an impressive number of ways. As experts in their field, nurse researchers can pursue a wide range of unique career advancement opportunities .

Why Nursing Research Matters: Examples of Research in Action

Research drives innovation in every industry. Given that nurses are on the front line of the health care industry, the research they do can be particularly impactful for patient outcomes. 

It Can Improve Patients’ Quality of Life

Patients diagnosed with life-threatening chronic diseases often undergo intense treatments with sometimes debilitating side effects. Nursing research is vital to helping such patients maintain a high quality of life.

For example, a 2018 study led by a nurse scientist explored why cancer patients undergoing chemotherapy frequently experience severe nausea. While the physical toll of chemotherapy contributes to nausea, the study found that patients who have factors such as children to take care of, high psychological stress, and trouble performing day-to-day tasks are often much more likely to experience nausea.

By identifying the root causes of nausea and which patients are more likely to experience it, this research allows health care professionals to develop evidence-based care practices . This can include prescribing anti-nausea medications and connecting patients to mental health professionals.

It’s Central to Making Health Care More Equitabl

A Gallup survey reports that about 38% of Americans put off seeking medical treatment due to costs. Unfortunately, cost is only one factor that prevents people from seeking treatment. Many Americans don’t live close to medical providers that can meet their needs, aren’t educated about health, or encounter discrimination.

As complex as this issue is, the National Institute of Nursing Research (NINR) asserts that the country’s nurse researchers can lead the charge in tackling it. In its strategic plan for 2022 to 2026, the institute highlights the following:

• Nursing has long been one of the most trusted professions in the country.
• Nurses often interact with patients, patients’ families, and communities more frequently than other health care professionals.
• The care that nurses provide must often take environmental and social factors into account.

These traits put nurses in the position to not only research health inequity but also put their research to work in their organizations. To help make that happen, NINR often funds nurse-led research projects focused on equity and social determinants of health. With that kind of backing, the field may become more transformative than ever.

It Can Strengthen the Health Care Workforce

While nursing research can be used to improve patient care, it can also be leveraged to solve issues health care professionals face daily. Research about the state of the health care workforce during the COVID-19 pandemic is a perfect illustration.

In 2022, a team of nurse researchers published a report called Nursing Crisis: Challenges and Opportunities for Our Profession After COVID-19 in the International Journal of Nursing Practice . In it, the authors provided concrete statistics about the following:

• Mental and physical health issues many nurses encountered
• Effects of increased workloads and decreased nurse-to-patient ratios
• How many nurses were planning to leave the profession altogether

As nurses themselves, the authors also offer actionable, evidence-based solutions to these issues, such as streamlining patient documentation systems and implementing employee wellness programs.

However, this type of research isn’t just important to solving workforce issues stemming from specific emergencies, such as the COVID-19 pandemic. By publishing quantifiable data about the challenges they face, nurse researchers empower other nurses and professional nursing organizations to advocate for themselves. This can help employers enact effective policies, support their nursing staff, and draw more talented people into the profession.

Career Opportunities in Nursing Research

Nurse researchers can work in any number of administrative, direct care, and academic roles. However, because nurse research often requires clinical care and data analysis skills, jobs in this field typically require an advanced degree, such as a Master of Science in Nursing (MSN).

While many more nurse research career opportunities exist, here are four career paths nurses with research experience and advanced degrees can explore.

Nurse Researcher

Nurse researchers identify issues related to nursing practice, collect data about them, and conduct research projects designed to inform practice and policy. While they often work in academic medical centers and universities, they can work for any type of health care provider as well as health care advocacy agencies.

In addition to conducting research, these professionals typically provide direct patient care. Many also write papers for peer-reviewed journals and make presentations about their work at conferences.

Clinical Research Nurse

Despite having a similar title to nurse researchers, clinical research nurses have slightly different responsibilities. These professionals are usually in charge of providing care to patients participating in medical research projects, including clinical trials and nursing research initiatives. They also typically collect data about patient progress, coordinate care between different team members, and contribute to academic papers.

Occupational Health Nurse

Also referred to as environmental health nurses, occupational health nurses serve specific communities, such as professionals in a particular industry or people who live in a particular area. They often educate their communities about relevant health risks, advocate for stronger health and safety regulations, and run wellness programs.

To carry out their duties, occupational and environmental health nurses must typically research health trends about the people they serve, including living and working conditions that put them at risk for illness or injury. They can work for private companies and government agencies.

Nurse Educator

Nurse educators prepare new nurses to enter the workforce or train experienced nurses in more advanced techniques. This can include teaching classes and providing on-the-job training. They often work for colleges, universities, and large health care providers.

While their duties don’t always include research, nurse educators must keep up with the health care industry’s needs and new patient care practices. This is so they can provide relevant education themselves and help their organizations design up-to-date curricula.

Make Nursing Research a Part of Your Journey

Conducting and implementing nurse research is a collaborative effort. It takes a team of informed leaders, skilled analysts, and creative educators to create effective, evidence-based policies. Those interested in pursuing nurse research should consider The University of Tulsa’s online MSN program , which can prepare you to fill any one of those roles and more.

All of TU’s MSN students take classes on research and evidence-based practices. However, the program’s specialty tracks allow students to take their studies in multiple research-oriented directions. For instance, if you’re interested in collecting and interpreting clinical data, you can choose the Informatics and Analysis track. If you have a passion for public health policy, the Public Health and Global Vision track includes classes on population health and epidemiology.

Delivered in a flexible online format, this program can be a great option for working nurses and nontraditional students alike. To find out more, read about TU’s admission policies and request more information today.

Recommended Readings

A Nurse Educator’s Role in the Future of Nursing

How Global Health Nursing Supports Population Health

What Can You Do With an MSN?

Gallup, “Record High in U.S. Put Off Medical Care Due to Cost in 2022”

International Journal of Nursing Practice, “Nursing Crisis: Challenges and Opportunities for Our Profession After COVID‐19”

Journal of Pain Symptom Management , “Risk Factors Associated With Chemotherapy-Induced Nausea in the Week Prior to the Next Cycle and Impact of Nausea on Quality of Life Outcomes”

Mayo Clinic, Nursing

National Institute of Nursing Research, Scientific Strategy: NINR’s Research Framework

National Institute of Nursing Research, The National Institute of Nursing Research 2022-2026 Strategic Plan

Recent Articles

How Leaders Drive Quality Improvement in Nursing

University of Tulsa

Aug 23, 2024

Wellness Nurse: Career Definition and More

Types of Nursing Degrees

Aug 21, 2024

Learn more about the benefits of receiving your degree from The University of Tulsa

• Online Program Tuition
• AGACNP Certificate Online
• Online MSN Program
• Accelerated Online BSN
• RN to BSN Program
• RN to MSN Program
• MS in Cyber Security
• Meet the Team
• Nursing Student Practicum Requirements
• Disclosures for Professional Nursing Licensure
• On Campus Programs

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
• Dialogues Clin Neurosci
• v.15(4); 2013 Dec

Memory: from the laboratory to everyday life

Daniel l. schacter.

Department of Psychology, Harvard University, Cambridge, Massachusetts, USA

One of the key goals of memory research is to develop a basic understanding of the nature and characteristics of memory processes and systems. Another important goal is to develop useful applications of basic research to everyday life. This editorial considers two lines of work that illustrate some of the prospects for applying memory research to everyday life: interpolated quizzing to enhance learning in educational settings, and specificity training to enhance memory and associated functions in individuals who have difficulties remembering details of their past experiences.

The study of memory lias progressed rapidly over the past few decades, and as illustrated by the papers in the current issue, it remains a thriving endeavor with many exciting new discoveries and ideas. But memory is not only a target for laboratory study; it is also fundamentally important in many domains of everyday life. This point is nicely illustrated by several articles in this volume addressing memory changes in neurological and psychiatric conditions that can have a profound impact on an individual's ability to function in daily life. Memory research has also been applied extensively in legal settings, where such issues as how to construct effective lineups and how to deal with the inaccuracy of eyewitness testimony are of paramount importance. 1 , 2 In this editorial, I discuss briefly some recent applications of memory research in educational and clinical settings that show promise for providing meaningful benefits in everyday life.

Enhancing attention and memory in educational settings

During the past several years, a rapidly expanding number of studies have attempted to apply principles and methods of cognitive psychology to educational settings. For example, one basic question concerns whether memory research can be used to increase the effectiveness with which students study for exams. In a recent comprehensive review, Dunlosky and colleagues 3 evaluated the effectiveness of ten different study methods, and characterized each one as being of either high, moderate, or low utility based on available research. Some of the popular methods commonly embraced by students—including rereading, summarizing, and highlighting—received low utility assessments. Only two techniques, both supported by data from numerous laboratory studies, received high utility assessments: distributed study, which involves spreading out study activities so that more time intervenes between repetitions of the to-be-learned information (as opposed to mass study or “cramming”), and practice testing, where students are intermittently given brief quizzes about what they have learned prior to taking a formal test.

The beneficial effects of practice testing for students are based mainly on studies demonstrating that the act of retrieving information can be a highly effective means of strengthening memory for the retrieved information. 4 Recent work in my laboratory has used a variant of the practice testing technique in an attempt to enhance attention and memory during video recorded lectures. 5 Students frequently experience lapses of attention both during classroom 6 and video 7 lectures. For example, when probed during either a classroom or online lecture regarding whether they are attending to the lecture or mind wandering to other topics, students indicated on approximately 40% of probes that they were mind wandering; not surprisingly, the extent of mind wandering was negatively correlated with retention of lecture content. 6 - 8

Our study 5 focused on video recorded lectures because they are a key element in online education, which has exploded during recent years, partly as a result of the development of massive open online courses (MOOCs). Consequently, understanding how to enhance learning from video lectures could have important implications for online education. Participants watched a 21-minute video recorded statistics lecture divided into four equal segments. After each lecture segment, all participants did math problems for a minute, after which the tested group received brief quizzes on each lecture segment that took about 2 minutes each; the nontested group continued to work on math problems for an additional 2 minutes and only received a test for the final segment; and the restudy group was shown, but not tested on, the same material as the tested group for each of the segments preceding the final segment. After the final lecture segment, all three groups received a quiz for that segment, and a few minutes later they also received a final test for the entire lecture. At random times during the lecture, participants in all groups were probed about whether they were paying attention to the lecture or mind wandering off to other topics.

Participants in the nontested and re-study groups indicated that they were mind wandering in response to about 40% of the probes, but the incidence of mind wandering was cut in half, to about 20%, in the tested group. Moreover, participants in the tested group retained significantly more information from the final segment of the lecture than did participants in the other two groups, and they also retained significantly more information on the final test of the entire lecture than did the other groups. While it is encouraging that interpolated quizzing can dramatically reduce the incidence of mind wandering and increase retention, the results reported must be treated with some caution, both because they were obtained only with a single lecture on a single topic, and also because it is unclear whether the benefits of interpolated quizzing persist across multiple lectures or in actual online (or live) classes. There is reason for optimism, however, because other kinds of practice testing have produced increased learning in classroom settings. 9

Increasing the specificity of memory

Consider next some recent research concerning a phenomenon that has been associated with a variety of troublesome symptoms in depressed individuals: reduced specificity of autobiographical memories. Several studies have shown that when asked to recall memories of everyday life experiences, depressed individuals tend to provide less specific detail about what happened during those experiences than do nondepressed controls. 10 This reduced specificity has been linked with problems such as excessive rumination and difficulties handling everyday interpersonal situations. 10 - 12 In light of these findings, a natural question concerns whether it is possible to increase memory specificity in depressed individuals, and whether such increases are associated with improvements in any of the problematic symptoms that had been linked with reduced memory specificity in previous research.

Recent studies 13 , 14 have addressed this question by demonstrating that several sessions of training that attempts to boost the specificity of memory retrieval in depressed patients (ie, practice with feedback in generating detailed, specific memories) increases the posttraining specificity of patients' autobiographical memories, even when controlling for associated improvements in depression. Neshat-Doost et al 13 reported that the gains from specificity training were maintained at a 2-month follow-up, and no improvements were evident in a control group. Raes et al 14 showed that increases in memory specificity after training were associated with improvements in everyday social problem solving and rumination. Although further research needs to be carried out to pinpoint exactly what features of memory specificity training are responsible for the observed improvements, the results to date are encouraging, and highlight how basic knowledge of the memory characteristics of a clinical population can be used to formulate an effective intervention.

Targeting autobiographical memory specificity seems especially useful because a growing number of studies have emphasized that autobiographical or episodic memory is used not just as a basis for remembering past experiences, but also for imagining possible future experiences 15 and related functions such as personal and social problem solving. 16 - 19 Consistent with these findings, recent research in our lab provides evidence that an induction aimed at increasing memory specificity in young and old adults had beneficial effects on both groups' performance of subsequent tasks that required either remembering past experiences or imagining possible future experiences. 20 Importantly, the effects of the induction were selective in two ways. First, the specificity induction (compared with a control induction) produced increases in the number of episodic details (eg, who, what, where, when) that participants remembered or imagined, but had no effect on the number of remembered or imagined semantic details (eg, general facts, commentary, impressions). Second, the influence of the specificity induction was restricted to memory and imagination tasks; it had no effect on a task that required participants to describe a picture of an everyday scene. These findings suggest that the induction targeted episodic memory in particular, and more generally, that specificity inductions can be used as experimental tools to distinguish among cognitive processes and representations that contribute to memory and related functions.

Concluding comments

The research reviewed in the preceding sections highlights ways in which memory research can be applied to educational and clinical settings. An important next step for this kind of research will be to investigate the neural mechanisms that mediate the observed effects on cognitive processes. How can we characterize the neural changes associated with improved attention and memory as a result of interpolated quizzing during lectures? What kinds of changes in brain activity are associated with the improvements produced by memory specificity training and how can they help to pinpoint the specific processes that are affected? Recent work in the domain of cognitive control has revealed that extensive training on a video game that requires multitasking skills led not only to improved cognitive performance in individuals ranging in age from their 20s to their 70s, but also to associated changes in brain activity that were predictive of cognitive improvements 6 months later. 21 Moreover, the study also yielded evidence that training served to remediate age-related deficits in neural markers of cognitive control. Applying such a cognitive neuroscience approach to the phenomena considered here should enhance our understanding of both theoretical and applied aspects of memory function.

Raw Milk Is Becoming More Popular – but According to Scientists, It’s More Dangerous Than You Think

Fewer than half of Americans are aware that drinking raw milk is less safe than drinking pasteurized milk.

Drinking raw milk or consuming products made from it carries more risks compared to pasteurized milk. However, according to the latest health survey by the Annenberg Public Policy Center, less than half of U.S. adults are aware that raw milk is less safe than pasteurized milk, and many do not recognize the associated health risks.

The survey finds that 47% percent of U.S. adults know that drinking raw milk is less safe than drinking pasteurized milk, while nearly a quarter (24%) of Americans either think incorrectly that pasteurization is not effective at killing bacteria and viruses in milk products (4%) or are not sure whether this is true (20%).

“It is important that anyone planning to consume raw milk be aware that doing so can make you sick and that pasteurization reduces the risk of milk-borne illnesses,” said Patrick E. Jamieson, director of the Annenberg Health and Risk Communication Institute at the Annenberg Public Policy Center (APPC) of the University of Pennsylvania .

APPC’s survey was conducted by SSRS, a market research company, on June 7-10, 2024, as a cross-sectional survey of 1,031 U.S. adults who are part of the SSRS Opinion Panel Omnibus. The margin of error for total respondents is ±3.5 percentage points at the 95% confidence level.

Why consuming raw milk is risky

Milk from animals including cows, sheep, and goats that has not been pasteurized to kill harmful germs is called unpasteurized or raw milk . Unpasteurized dairy products are estimated to “cause 840 times more illnesses and 45 times more hospitalizations than pasteurized products.” The Centers for Disease Control and Prevention (CDC) says that consuming unpasteurized milk and products made from it “can expose people to germs such as Campylobacter , Cryptosporidium , E. coli, Listeria, Brucella, and Salmonella. ”

Heightening these concerns, the Food and Drug Administration (FDA) reported in an open letter on June 6, 2024, that bird flu has been detected in cow’s milk. Cattle infected with avian influenza “shed the virus in their milk.” Technically known as highly pathogenic avian influenza virus (HPAI) of the H5N1 subtype, the CDC has noted that H5N1 bird flu is “widespread in wild birds worldwide and is causing outbreaks in poultry and U.S. dairy cows.” The presence of H5N1 bird flu was confirmed in cattle in the United States in mid-March 2024. As of June 21, 2024, there had been four human cases of H5N1 in the United States since 2022, three in April and May of 2024 following exposure to cows and one in April 2022 following exposure to poultry. As of mid-June, 95 cattle herds in 12 states were identified as infected .

The FDA says it does not currently know whether the HPAI H5N1 virus can be transmitted to humans through consumption of raw milk and products made from raw milk from infected cows. However, a study conducted in mice concluded that the virus in “untreated milk can infect susceptible animals that consume it” and the National Institutes of Health (NIH) says this suggests that drinking raw milk “may pose a risk of transmission to people.” As of mid-June 2024, the FDA concluded “that the totality of evidence continues to indicate that the commercial milk supply [which is pasteurized] is safe.”

Although the FDA has prohibited the interstate sale of raw milk since 1987, 30 states in the United States allow the sale of raw dairy milk in some form, according to the NIH. While an FDA food safety report in 2016 said just 4.4% of U.S. adults reported consuming raw milk at least once in the past year, raw milk sales have been increasing, according to the Associated Press, which reports that weekly sales of raw milk from late March to mid-May grew from 21% to as much as 65% over the same period last year.

What people know about the risks of raw milk and benefits of pasteurization

The CDC notes that “pasteurization is crucial for milk safety, killing harmful germs that can cause illness” and the NIH says “dairy milk purchased in the grocery store has been pasteurized – heated to a level high enough and long enough to kill most viruses or bacteria in the milk.”

Yet in the APPC survey, over half of the respondents (54%) either think drinking raw milk is safer (9%), just as safe (15%), or are unsure (30%) whether it is more or less safe than drinking pasteurized milk. Nearly a quarter of those surveyed question the effectiveness of pasteurization at killing bacteria and viruses in untreated milk – 20% are unsure whether it is effective and 4% incorrectly assert that it is not effective.

Who holds correct and mistaken beliefs about raw milk?

An analysis of survey data shows that adults who are 65 and older, college educated, or who identify with the Democratic Party are more likely to understand the benefits of pasteurization and to believe that pasteurization does not destroy the nutrients in milk. The survey finds that Democrats are more likely than Republicans to believe that drinking raw milk is less safe than pasteurized milk (57% vs. 37%). People living in an urban environment also are more likely to believe that raw milk is less safe than pasteurized milk than people in a rural environment (49% vs. 32%).

“The difference in views of raw milk that we see between Democrats and Republicans is difficult to disentangle from the difference between rural and urban dwellers,” said Kathleen Hall Jamieson, director of the Annenberg Public Policy Center. “Those in rural areas are both more likely to identify as Republicans and to consume raw milk .”

However, a regression analysis conducted by APPC research analyst Shawn Patterson Jr. shows that both which political party one identifies with and where one lives independently predict an individual’s beliefs about the safety of raw milk. But the analysis also shows that where one lives does not independently predict beliefs about the effectiveness of pasteurization nor the effect pasteurization has on the nutrients of milk. (See the appendix for regression analysis.)

The nutritional value of pasteurized vs. raw milk

Viral online videos championing the purported benefits of raw milk attracted millions of views between late March, when the presence of bird flu virus was first confirmed in U.S. cattle, and mid-May, according to reports in the Associated Press and Washington Post . Drinking raw milk has been encouraged as well by some political leaders, including presidential candidate Robert F. Kennedy Jr., who told the audience at an October 2022 meeting of his Children’s Health Defense that he drinks raw milk exclusively .

Among the arguments advanced in favor of consuming raw milk is that pasteurization destroys valuable nutrients – but the CDC states that pasteurized milk “offers the same nutritional benefits without the risks of raw milk consumption.”

Our survey finds that less than half of Americans (43%) know that pasteurization “does not destroy nutrients in milk,” while 16% believe that it does destroy nutrients and 41% are not sure. Notably, the survey finds that younger people (18- to 29-year-olds) are more likely to believe than older adults (65 and older) that pasteurization destroys the nutrients in milk (25% vs. 5%) and Republicans are much more likely to believe it than Democrats (23% vs. 8%). Whether one lives in an urban vs. rural setting is not significantly different in this belief.

APPC’s survey

This study was conducted for APPC by SSRS, on its Opinion Panel Omnibus platform. The SSRS Opinion Panel Omnibus is a national, twice-per-month, probability-based survey. Data collection was conducted from June 7–10, 2024 among a sample of 1,031 respondents. The survey was conducted via web (n=1,001) and telephone (n=30) and administered in English (n=1,005) and Spanish (n=26). The margin of error for total respondents is +/-3.5 percentage points at the 95% confidence level. All SSRS Opinion Panel Omnibus data are weighted to represent the target population of U.S. adults ages 18 or older.

In addition to Patrick Jamieson, Kathleen Hall Jamieson, and Shawn Patterson Jr., APPC’s survey team includes Ken Winneg, managing director of survey research.

Download the topline , appendix , and methodology statements.

Related Articles

New study: vitamin d could ease psoriasis severity, new harvard research links omega-3 fatty acid consumption with slower als progression, why you should eat more live microorganisms, bad for planet and health: new study reveals alarming truth about keto and paleo diets, adding just a small handful of walnuts to diet can have important benefits, harvard study links a variety of healthy eating patterns to a lower risk of premature death, inorganic food additives might make babies more vulnerable to potentially life-threatening allergies, are diets healthier today or were they 30 years ago, study finds new health benefits of walnuts.

If you are drinking milk from animals you know, whose health you can vouch for, then it is probably the healthiest. If you don’t know the health of the animal, then it is riskier.

It is interesting that the current trend against processed foods doesn’t seem to apply to pasteurization, which is a food processing method.

It should have been mentioned that pasteurized, commercial milk comes in plastic or wax containers that can leach chemical contaminants into the milk. Raw milk usually comes in a glass mason jars from the farm.

Strange, and interesting, that they asked about political party. Democrats seem to be more concerned with controlling things than Republicans.

we need to ask who paid for this study and who benifits from it?

Raw milk consuming means less earnings for milk companies that make it like water taking off all the butter

Save my name, email, and website in this browser for the next time I comment.

Type above and press Enter to search. Press Esc to cancel.