how does research study help you in your daily life

What is the importance of research in everyday life?

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

Research increases the quality of life

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

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

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

Research empowers us with knowledge

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

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

Research drives progress forward

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

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

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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.

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.

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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.

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Why does research matter?

Victor h hu.

Assistant Clinical Professor: International Centre for Eye Health, London School of Hygiene & Tropical Medicine and Consultant Ophthalmologist: Mid Cheshire NHS Hospitals, UK.

A working knowledge of research – both how it is done, and how it can be used – is important for everyone involved in direct patient care and the planning & delivery of eye programmes.

A research coordinator collecting data from a health extension worker. ethiopia

The mention of ‘research’ can be off-putting and may seem irrelevant in the busy environment of a clinic or hospital. However, research is central to all aspects of eye care delivery – both inside and outside the clinic.

Whether we are health workers, public health practitioners, managers, policy makers, or editors – all of us ‘stand on the shoulders of giants’: we rely on the research done by others before us. This can be as simple – and profound – as hand washing between patients; a habit that only became common practice in the 1870s, following the work of the Hungarian physician Ignaz Semmelweis and Scottish surgeon Joseph Lister. Or it can be as complex as making a diagnosis of glaucoma and knowing what treatment to give. All current eye care practice is based on research. Clinical, operational (eye care delivery) and public health practice will continue to be profoundly shaped by new research developments.

What is research?

In its simplest form, research is about investigating the world around us to increase our knowledge, so we can work out how to do things better.

In health care, we use a scientific approach to carry out research; there is a set way of doing things that ensures research is done in a logical way, and that results are published widely, so that other people can scrutinise what has been done. This gives us confidence that the results will be useful in everyday practice.

It is important to critically evaluate research and research findings, including checking that research has been carried out in the proper way, and whether the conclusions that have been made are reasonable and justified. One of the ways in which the scientific community ensures the quality of research is through the process of peer review. Before research papers are accepted for publication in a scientific journal, they are reviewed by other researchers (peer reviewed) to check the quality of the research and the validity of the results and conclusions. Even so, the quality of published research can vary.

This is why systematic reviews and meta-analyses are so valuable: they answer important questions by identifying, evaluating, and summarising good quality evidence from a range of published research papers. Often, systematic reviews conclude that there is not enough evidence to answer a question with absolute certainty, or to produce an answer that will be applicable in different countries or health care settings. This is useful, as it gives researchers guidance about where more research is needed (see article on page 13).

But this can be a challenge for clinicians – how can we make good decisions in the absence of definitive evidence? Clinical experience is very important, but where possible this should be informed by good research – see page 6 for practical tips.

Health care practitioners and managers can also use guidance from professional bodies such as the World Health Organization. The article on page 8 explains the process by which guidelines are developed and shows why we can rely on them.

In conclusion, research is fundamental to the everyday practice of health care professionals, including eye care workers. Research allows us to find out new things and to provide better care for patients. There are many different types of research that can be carried out and these can vary enormously. It is important to ask the right question, as this will determine the type of research that is done (see page 5).

All of us can participate in research: it starts with asking questions and then going to find out the answers. The article on page 10 offers practical suggestions for carrying out small-scale research that is relevant and useful to eye care.

Types of health research

Basic science research, such as in molecular genetics or cell biology, fills the gaps in our understanding of disease mechanisms (pathogenesis).

Clinical research addresses how diseases in individuals can present and be diagnosed, and how a condition progresses and can be managed.

Epidemiological research , which is at the population level (as opposed to the individual level), answers questions about the number of people in the population who have a condition, what factors (called exposures) are causing the condition, and how it can be treated or prevented at the population level.

Going beyond epidemiology, there is also operational and health systems research , which focuses on how best to deliver health interventions, clinical and rehabilitation services, or behaviour change initiatives.

Other types of research , which are also important for public health, include health economics, social science, and statistical modelling.

Finally, systematic literature reviews can be very useful, as they identify and summarise the available evidence on a specific topic.

By Clare Gilbert and GVS Murthy

Examples of research questions and how they have been answered

Can povidone iodine prevent endophthalmitis.

In many eye departments, cataract surgery is a frequently preformed operation. One of the most serious complications is infection within the eye (endophthalmitis) which can lead to loss of vision. Several well conducted randomised controlled clinical trials have shown that instilling 0.5% aqueous povidone iodine eye drops, an antiseptic agent, before surgery reduces the risk of this devastating infection, with the first trial undertaken in 1991. 1

What is the best treatment for primary open-angle glaucoma?

Chronic glaucoma can be a very difficult condition to manage, particularly when patients often only present to eye departments once they have already had significant vision loss. Eye drops which lower intraocular pressure are often prescribed; however, patients may not use the eyedrops because they are expensive, can be difficult to instil, and do not improve their vision. Surgery is an option, but patients can be reluctant to undergo surgery on their only good eye, and there can be postoperative complications. Laser treatment is another option. In a recent study in Tanzania, patients were randomly allocated to Timolol 0.5% eye drops or a form of laser called Selective Laser Trabeculoplasty (SLT). 2 After one year, SLT was found to be superior to drops for high-pressure glaucoma.

Why don't older adults in England have their eyes examined?

Focus group discussions among older adults in England revealed that, despite most participants being eligible for state-funded check-ups, wearing spectacles was associated with the appearance of being frail. They were also afraid of appearing to ‘fail’ tests, and had concerns about the cost of spectacles. 3

How cost effective is a diabetic retinopathy screening programme?

An economic evaluation in South Africa compared alternative interventions. Screening using non-mydriatic retinal photographs taken by a technician supervised by an ophthalmic nurse and read by a general medical officer was cost-effective and the savings made allowed the government to fund disability grants for people who went blind. 4

Acknowledgements

Stephen Gichuhi and Nyawira Mwangi contributed to preliminary work on this article.

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Measuring everyday life: Talking about research and why it matters

Edited by Brian G. Southwell , Karen Keaton Jackson, Bridget Pittman-Blackwell.

February 02, 2022 Open Access Peer Reviewed

DOI: 10.3768/rtipress.2022.bk.0025.2201

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• Curated from interviews featured on the public radio show, The Measure of Everyday Life, this collection reveals ways that we can ask useful questions.
• The book also offers insights from behind the scenes of social science research, communication campaigns and interventions, and community engagement projects.
• A wide range of audiences—including anyone interested in applying academic research to practical projects, new graduate students, and undergraduate students learning about research—should find useful material in the collection.

“Asking questions, good questions asked the right way, is the basis for so much of the work I do. This book is a timely look at why those questions and the research that propels them matter. We are at precisely the moment when there are so many players in our public discourse that need to take lessons from inside these pages.”

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Dr. Rachel Powell, CDC Foundation and Georgia State University

“This book invites you into truly wide-ranging—and highly accessible—conversations about how researchers work, how they sometimes surprise themselves as they dig into a topic, and what their work tells us about a whole host of pressing issues, ranging from artificial intelligence to end of life, to the language we use to talk to our kids about obesity, to the role of ‘back roads’ in rural Black communities in the south. Fascinating and thought-provoking.”

Joanne Kenen, Commonwealth Fund Journalist in Residence, Johns Hopkins University, and contributing editor for Politico

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What Is Research, and Why Do People Do It?

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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.

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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

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In This Article Expand or collapse the "in this article" section Research Methods for Studying Daily Life

Introduction, general overviews.

• Study Designs and Sampling Methods
• Advantages and Limitations of Daily-Life Methods
• Sampling and Measurement Considerations
• Technology/Equipment for Daily Assessments
• Additional Considerations and Future Directions

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Research Methods for Studying Daily Life by Carla Arredondo , Gloria Luong LAST REVIEWED: 24 April 2019 LAST MODIFIED: 24 April 2019 DOI: 10.1093/obo/9780199828340-0243

Methods for studying daily life have blossomed since the 1980s. Although these methods have been around for years, their popularity is always increasing as technological innovations have made the use of these methods easier and more reliable to employ. Methods for studying daily life typically include taking repeated real-time assessments of individual behaviors, physiology, and/or psychological experiences, over the course of an individual’s everyday life. These methods include experience sampling methodology (ESM), ecological momentary assessments (EMA), ambulatory assessments (AA), and daily diary or day reconstruction methods. All of these methods include repeated or detailed assessments of daily- life experiences but vary in terms of the frequency of assessments, technological tools to administer assessments, and timing of assessments (e.g., real time assessments versus retrospective recall). Given that these methods are intended to capture observations of psychological experiences in daily life, they require careful consideration of study design, measurements, and assessment tools. This article will provide a general overview of daily-life methods, including discussions about the different study designs and sampling methods. Furthermore, it will describe the advantages and limitations of using these methods along with examples of empirical studies that illustrate the usefulness of these techniques. It will also provide information on important considerations for sampling and measuring experiences in daily life and provide examples of the technology available for daily-life assessments.

Mehl and Conner 2012 is an all-encompassing review that discusses theoretical, methodological, and statistical considerations for conducting daily-life studies. Conner and Lehman 2012 focuses on providing practical advice for designing and conducting daily-life studies, while Stone and Shiffman 2002 outlines standardized reporting guidelines for researchers and provides recommendations for the information that should be included in study reports. Broderick, et al. 2003 and Green, et al. 2006 discuss issues of participant compliance and provide examples of how to monitor and improve participant compliance in daily-life studies. Barta, et al. 2012 discusses issues of measurement reactivity, whereby measurements bring about changes in study participants, and Conner and Reid 2012 is an example of testing for measurement reactivity. Lastly, Bolger, et al. 2003 provides an outline of areas of research that will need further investigation as intensive longitudinal designs become more prevalent.

Barta, W. D., H. Tennen, and M. D. Litt. 2012. Measurement reactivity in diary research. In Handbook of research methods for studying daily life . Edited by M. R. Mehl and T. S. Conner, 89–107. New York: Guildford Press.

Reviews factors that can affect measurement of constructs in daily-life studies. Discusses some of the sources of measurement reactivity, such as social desirability of the construct under investigation and conditions that influence reactivity of self-monitoring, such as participant motivation. They conclude with a review of studies demonstrating mixed findings on measurement reactivity and recommend that more daily-life studies explicitly test for measurement reactivity.

Bolger, N., A. Davis, and E. Rafaeli. 2003. Diary methods: Capturing life as it is lived. Annual Review of Psychology 54:579–616.

DOI: 10.1146/annurev.psych.54.101601.145030

Discusses areas of research that will need further consideration as intensive longitudinal study designs become more common. The article also discusses using technology to monitor objective measurements, such as heart rate, in conjunction with subjective experiences (i.e., mood). Also covered is the need to develop and test measures that can capture within-person changes and ideas for formulating research questions to further understand how these processes unfold in everyday life.

Broderick, J., J. Schwartz, S. Shiffman, M. Hufford, and A. Stone. 2003. Signaling does not adequately improve diary compliance. Annals of Behavioral Medicine 26:139–148.

DOI: 10.1207/S15324796ABM2602_06

Tested the extent to which signaling participants, via a programmed wristwatch, improved compliance in a twenty-four-day experience sampling study of individuals with chronic pain. The study used photo sensors to detect when diaries were opened and closed by participants to make an entry, and this information was cross-referenced with participant self-reports of compliance.

Conner, T. S., and B. Lehman. 2012. Getting started: Launching a study in daily life. In Handbook of research methods for studying daily life . Edited by M. R. Mehl and T. S. Conner, 89–107. New York: Guildford Press.

Provides an overview of important considerations for designing and conducting daily-life studies. It begins with preliminary considerations, such as participant characteristics, and moves into sampling strategies and platforms. Practical concerns, such as ethical considerations, are also discussed.

Conner, T. S., and K. A. Reid. 2012. Effects of intensive mobile happiness reporting in daily life. Social Psychology and Personality Science 3:315–323.

DOI: 10.1177/1948550611419677

An example of an experience sampling study that explicitly tested measurement reactivity. The study examined the extent to which there was measurement reactivity in a measure of happiness. Results demonstrate that overall the measure in question did not show reactivity. However, participant characteristics, such as depressive symptoms and trait neuroticism, contributed to measurement reactivity.

Green, A. S., E. Rafaeli, N. Bolger, P. E. Shrout, and H. T. Reis. 2006. Paper or plastic? Data equivalence in paper and electronic diaries. Psychological Methods 11:87–105.

DOI: 10.1037/1082-989X.11.1.87

See this article for a brief review of concerns regarding participant compliance in diary studies (pp. 87–88). The article also discusses other issues such as important considerations for improving the data quality from diary studies, recommendations for defining compliance, and individual differences in compliance (pp. 102–104). The article concludes with recommendations for improving diary studies.

Mehl, M. R., and T. S. Conner, eds. 2012. Handbook of research methods for studying daily life . New York: Guildford Press.

This book provides an all-encompassing review for researchers conducting daily-life studies. It is a resource for conducting high-quality research and provides guidelines to select and implement methods for studying daily life. The book begins with fundamental theoretical and methodological considerations for conducting these studies and then reviews statistical techniques that can be used to analyze these data. The book concludes with examples of these methods and techniques across different sub-fields in psychology.

Stone, A. A., and S. Shiffman. 2002 Capturing momentary, self-report data: A proposal for reporting guidelines. Guidelines for Momentary Research 24:236–243.

Proposes criteria for collecting momentary data. Argues that strategies for sampling daily-life data should be based on theoretical, statistical, and practical considerations of the phenomena in question that allow researchers to adequately collect data for hypothesis testing. The article also provides recommendations on reporting guidelines to facilitate study replication.

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Research impact: what it is, why it matters, and how you can increase impact potential

Every drop of funding now seems to come with requirements around achieving and demonstrating broader impacts. Not many of us disagree with that in principle, but what does it mean in practice? How is impact actually achieved? How can you measure it? What can you actually do to accelerate it? Here’s what our co-founder Charlie Rapple had to say in a recent webinar .

This post is 10 minute read. Here is your 1 minute summary:

• Research impact is real change in the real world.
• There are many different kinds of impact including attitudinal, awareness, economic, social, policy, cultural and health.
• It takes hard work and persistence to create impact from research.
• Impact is achieved through several steps that include helping relevant audiences to discover, connect with, understand, apply and advocate for research.
• Impact is best achieved through stakeholder engagement throughout the lifecycle of a project.
• National assessment programmes and funding agencies are placing increased emphasis on dissemination and impact evaluation, particularly outside of academia.
• Evidencing and measuring impact are controversial and fast developing areas – likely to comprise a mix of quantitative indicators and qualitative reviews.
• Researchers will need to develop new skills and capabilities to demonstrate ability to create impact, which could become central to career progression and institutional reputation.
• Find out more about our new platform to help you plan and manage communications to maximize the impact potential of your research .

1. What is research impact?

• US National Institutes of Health : The likelihood for the project to exert a sustained, powerful influence on the research field(s) involved.
• Research England : An effect on, change or benefit to the economy, society, culture, public policy or services, health, the environment or quality of life beyond academia.
• US National Science Foundation : The potential [for your research] to benefit society and contribute to the achievement of desired society outcomes.
• Australian Research Council : The contribution that research makes to the economy, society, environment or culture, beyond the contribution to academic research.

While there are some subtle differences, they broadly agree that “impact” means demonstrable and beneficial change in behaviours, beliefs and practices. At Kudos, we like the simplicity of this definition from Julie Bayley , Director of Research Impact at the University of Lincoln:

“Provable change [benefit] of research in the ‘real world’.”

The real world part is key. Traditionally, assessment of impact has focused too much on academic impact – whereas, in reality, impact is measured by indicators of change outside universities and research institutions, in the real world.

Having defined impact at this high level, it’s then possible to define a number of types of impact. Professor Mark Reed , Director of Engagement & Impact at Newcastle University, has analyzed impact case studies from around the world, and proposes ten types of impact:

• Understanding and awareness – meaning your research helped people understand an issue better than they had before
• Attitudinal – your research helped lead to a change in attitudes
• Economic – your research contributed to cost savings, or costs avoided; or increases in revenue, profits or funding
• Environmental – benefits arising from your research aid genetic diversity, habitat conservation and ecosystems
• Health and well-being – your research led to better outcomes for individuals or groups
• Policy – your research contributed to new or amended guidelines or laws
• Other forms of decision-making and behavioural impacts
• Cultural – changes in prevailing values, attitudes and beliefs
• Other social impacts –such as access to education or improvement in human rights
• Capacity or preparedness – research that helps individuals and groups better cope with changes that might otherwise have a negative impact.

Professor Reed’s book, The Research Impact Handbook , is highly recommended – even required reading – if you’d like to learn more about each of these areas, and how to understand the potential outcomes of your research in each area.

2. Why does impact matter?

A focus on impact, then, helps us ensure the best possible return from the investments that we – as a society– are making in research.

At a more everyday level, research impact matters to individual researchers because it matters to funders! The organizations that control research funding are under pressure to audit and evaluate their spending. For example, government policy makers want to know that they can rely on government-funded research to be high quality and highly relevant. Charitable funders need to be able to show donors how outcomes are being improved as a result of their donations. Institutions such as universities want to prove that they are the best, to attract more students, more researchers and more donations.

3. How is impact achieved?

Because of the role that past and potential impact plays in funding decisions, this is literally a billion dollar question. There is no single, simple answer. But the question of what kinds of steps help to achieve impact has been widely considered.

• Reach : communication of knowledge is key to impact. You need to reach the audiences that can best build on or benefit from your work. Why? Your findings will not be able to deliver any kind of change if no-one knows about them.
• Engage : you need to interact with those audiences – whether they are policy makers, industry, educators, healthcare practitioners, the media, or the public – to understand their needs and existing level of expertise, and to be able to address their feedback as your work evolves. Why? Your findings will not be able to deliver any kind of change if they are not relevant to potential stakeholders or beneficiaries, or if they cannot understand them.
• Change: you need to be thinking from early in the research process about the kind of change you want to create – whether that is changing behaviours, attitudes, awareness, processes, policy, product specifications (see Mark Reed’s ten types of impact, above). Why? As above – impact must be more than an academic concept for it to be truly valued by the real world, and thus by research funders and institutions.
• Amplify: you need to think about how any change you can bring about will scale such that its effect is as significant, widespread and lasting as possible. For example, how can a benefit to the local community be translated to national or even international impact? Why? To maximize the impact potential of your work, and the return on the investment that you and your institution or funder have made.

An important point to remember in this context is that routes to impact are not, in themselves, impact. Running a workshop, producing a report, meeting a company are all activities that can help you progress through this process. But in themselves they don’t represent provable change in the real world. It may be easier to track and measure those pathways than it is to identify the downstream outcomes that result from them.

This is one of the problems we’re working on at Kudos, helping researchers to capture the breadcrumb trail to link impact back to these activities. You can read more about our platform for this here .

4. How is impact measured?

• Advocacy – helping gain support from the public, funders, government etc
• Accountability – showing what you are achieving with your work
• Analysis – finding out which approaches to research are most effective
• Allocation – considering where it is most appropriate to invest research funding.

Measuring impact is notoriously difficult (hence many funders and systems still resort to using publication-based proxies such as the Impact Factor or citation counts – which really reflect routes to impact rather than impact themselves, and even then, only within academic audiences). A more nuanced way of assessing impact is through narrative-based case studies, or by looking at tangible outcomes – impact evidence – that can be recorded and reported on via impact trackers or impact modules within university systems. Trish Greenhalgh writes and speaks eloquently on this subject. In her view, there is a trade-off between breadth and depth. If you want to measure the impact of every bit of research that everyone in a university has ever done, you have to use something that is easy to measure and probably automated. But if it is more important to get a rich and authentic picture of a sample of research programmes, this needs to be looked at in a lot more detail – balancing measures with narrative. The Metric Tide report (produced by the Higher Education Funding Council in the UK) also concluded that quantitative measures can’t yet replace qualitative assessments of quality and impact.

There is a lot more work to be done here! What is perhaps more measurable are the various steps from access to impact that we explored above; efforts to maximize reach, engage audiences, achieve and amplify change are all increasingly measurable. Over time, as those measures can be linked with ultimate outcomes, we will learn more about not only how to measure impact, but what to do to achieve it, too.

Charlie Rapple is one of the founders of Kudos, which has recently launched a new platform to help plan and manage communications to maximize impact potential of research . Charlie previously spent 20 years as a marketing and communications specialist in the academic sector, helping publishers and universities to communicate research.

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What is knowledge mobilization? Or, how do I develop the impact potential of my research?

Given the role that impact plays in decisions around research funding, the question of how to achieve and accelerate impact is literally a billion.

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How analyzing communications data improves research engagement and impact

I was delighted to be invited to speak at last week’s “Strategy of Impact” conference, organised by ResearchFish and Interfolio. My paper explored.

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Research and Its Importance for Daily Life Essay

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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.

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Why and How does Research Matter in a Student’s Life?

The essence of student life is lost in the quest to be a class topper. Unfortunately, the world only cares about a report card and top grades. Bereft of choice, students take the easy way out  they lose interest in going above and beyond the academic curriculum. Is a degree just a means to financial independence? What about the fire, the passion for exploring unchartered territory? What about innovations that can change the world?

Only a handful of students understand that research has the power to change the world, to change the very fabric of our being, and to create something innovative and novel.

Every student should go through the journey of research, see why?

Success comes from curiosity, concentration, perseverance and self-criticism  Albert Einstein

The irresistible desire to learn and know new things is the foundation of research. A curious student will observe, question, experiment, and then learn. This will lead him to discover and uncover new things, which may change the face of the world forever.

Research is critical for improving society, sustaining the economy, propelling innovation, and tackling problems that ordinary people confront daily. Studying, analysing, experimenting and discovering teach students about our rich history and help them understand our present context and plan their future.

The research component provides a comprehensive learning experience as students can investigate the impact of implementing new thought processes through research and testing. Discoveries are being made in numerous domains daily, particularly science-related, and research is at its centre.

Research keeps you from lagging or harbouring inaccurate information about a subject. You might utilise the most recent data to expand on ideas or speak eloquently about a topic. This brings us to the second point about establishing credibility.

Research enables us to tackle global challenges and make evidence-based decisions. It sheds light on issues that have remained buried for long and allows people to discuss concerns and answer questions that society does not address.

Let us discuss why and how research matters in a students life.

Research for self-sufficiency: Importance

The benefits of scholarly research in higher education are innumerable. With a more functional deep dive into the subject matter under investigation, students improve their capacity to analyse and discuss any topic. The educational journey of research helps students learn all about current discussions. Developing essential library skills is a huge benefit to becoming self-sufficient. Thus, research aids in evaluating other writing styles and improving one’s reading and writing skills. A thoroughly explained bibliography is often an essential initial step in performing scholarly research. Reviewing, assessing, and synthesising information from multiple sources helps students improve their critical thinking power. Research takes effort and time, but it can yield enormous benefits and help students grow personally & professionally.

Find, measure & grab opportunities

Research is a way to nurture students potential and diversify opportunities and goals. This includes obtaining work, receiving scholarships or grants, project funding, beginning a business relationship, or getting other minor victories. These opportunities can help broaden one’s social network, raise awareness or start a new business or a project. Its a way to help people make the right life-changing decisions. This helps in self-growth and productive living.

Industry & research

When in need, industries inadvertently turn to academics to solve vital issues. The need to share knowledge, explore, innovate, and create is paramount to industrial and research interdependency. Without academic research, it is impossible to plan, strategise, and discover solutions. Thus, global development is dependent on research in higher education institutions .

Encourages research-based practice & knowledge production

In-depth research during higher education motivates students to publish their journals, implement research activities in studies, etc. Thus, educational institutes, colleges, and universities should also understand the significance of research and design their academic curriculum accordingly. This can be achieved if individually assigned professors encourage and mentor students in researching and writing high-impact journal publications.

Start your research journey with Shoolini Universitys elite programs

In the modern age of dynamic globalisation, research cannot be conducted in isolation. As a result, the importance and demand for research-driven universities have grown exponentially.

Shoolini, India’s No.1 Research University , has always been at the forefront of research-based education. Shoolini University is ranked first in India and 9th in Asia for citations per paper by QS World University Rankings Asia 2023 .

The institution is located in the foothills of the Himalayas and is well-known for its treasure trove of herbs. The infrastructure is designed to foster cutting-edge research in various fields such as science , engineering , yoga , management , and liberal arts .

Shoolini University is also well-known for its elite research programs. To make these programs more impactful, students are given hands-on experience with cutting-edge research and are guided to create technical articles. Personal mentoring elevates the curriculum to a new level, transforming it into a research-based Shoolini University innovation.

Shoolini has maintained an H-index (index used to assess Research Output and Quality) of 100, the highest for any university created after 2009. The FWCI is 2.22, which is equivalent to the top 10 worldwide colleges. Students and professors have submitted over 1200+ patents , making it the top research institution in India.

Artificial intelligence, bioenergy, biofuels, ageing and nutrition, drug discovery for cancer, genomics, water purification, probiotics, and other fields are being researched broadly at Shoolini university.

Shoolini has been placed third in patent filings (2019), joining the ranks of research institutions such as IITs and IIMs.

Shoolini’s dedicated research centres aid in achieving these goals. These centres offer comprehensive research facilities for producing qualitative research findings. Recognition from major institutes such as SCIMAGO and QS Rankings validate that Shoolini Research Centres have performed splendidly.

Benefits of taking part in Shoolini research programs:

• You can work closely with a faculty mentor and have the opportunity to network with academic and student researchers in your field.
• You can earn academic credit, scholarships, stipends, and/or other awards for research efforts.
• You can hone leadership and teamwork skills.
• You can acquire academic credentials to build a well-rounded resume by publishing works and collaborating with a research team.
• You can learn essential skills, such as how to use online research tools.
• You can learn vital life and classroom skills (professionalism, time management, multi-tasking).
• You can learn how to effectively communicate thoughts while analysing and criticising the work of others.
• You can better grasp scientific processes as you design research questions, form hypotheses, and test them.
• You can learn to work in a lab, plan studies, write grants, and report findings.
• You may be compensated, sometimes as an employee, sometimes as a scholarship recipient.
• You have the option to publish your work. If you assist a faculty member, they may acknowledge your work, or you may mention your work.
• This is an excellent opportunity to meet faculty members who work in your field of interest and network with fellow researchers. After developing a solid working relationship with them, you can request a letter of recommendation from a faculty mentor.

Also read: Benefits of Conducting Research at Indias No.1 Research University

Realising the need to promote research that can develop solutions to world problems and issues, Shoolini University has risen to the top. Its support for researchers and sustained research activities have resulted in ground-breaking innovation and the filing of more than 1200 patents. No wonder Shoolini researchers have featured in the World’s Top 2% Scientists List released by Stanford University.

Impactful research that can change the world is in high demand. You can join this exclusive group of scholars by enrolling in any research program at Shoolini University!

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5 Examples of How Sociology Impacts Everyday Life

February 28th, 2022 by JWU

Sociology employs a wide range of approaches to study social relationships and human behavior across our society and within many areas of our lives. Sociologists evaluate and examine subject matter such as crime, religion, family relationships, racial and gender identity, class divisions, communities, cultures, and social stability. 

Understandably, there are many examples of sociology in everyday life. Sociology provides a unique and illuminating perspective on how we, as complex human beings, influence our society, our relationships, and our culture as a whole. 

WHAT IS SOCIOLOGY?

Sociology serves as one of many branches under the social sciences umbrella that studies relationships among individuals within different societies. Sociology is the study of life in action — examining how individuals act and evolve within social groups while understanding the causes that influence behavior. Social interaction, or how individuals engage with and react to others, is a critical component of our collective society.

The premise that the person and society are intertwined is a crucial foundation of the sociological worldview. It isn’t easy to study one without also examining the other. This dual and comprehensive focus allows experts in this field — often referred to as sociologists — to study how individuals impact society and how society impacts individuals.

WHAT IS A SOCIOLOGIST?

A sociologist utilizes various research methods to study society to learn more about social interactions with groups and how individual and collective experiences shape our behavior. A sociologist may study behavior within small-scale groups, such as family and friend relationships, as well as international institutions, such as economics, government, global relations, and more.

Examples of sociology could include studying the relationship between culture and society, examining social movements, or researching how communication affects human behavior. Sociology can be divided into several subfields, including criminology, political science, social work, sociology of health and illness, gender studies, and race/ethnicity studies.

A sociologist believes that an individual’s personal decisions do not exist in a vacuum. We, as individuals, are influenced by cultural trends, beliefs, and values, which impact our behavior. Sociologists identify and evaluate these factors through sociological research, which includes studying the behavior of the larger collective group, comprised of individuals in the same area under the same societal influences.

Sociologists evaluate human behavior by examining individual encounters, group interactions, and social processes. Micro-level sociologists investigate individual encounters, or face-to-face interactions, in small groups. For example, a micro-level sociologist may look at the accepted rules of discourse among distinct groups, such as teens or business executives. Prior to the pandemic, such study may have focused on in-person interactions. Today, sociologists provide insight into understanding how virtual and hybrid environments impact behavior.

While micro-level sociologists focus on small groups, macro-level sociologists investigate patterns within and between larger groups and societies. A macro-level examination may investigate how language use has evolved over time or in social media channels. Additionally, a macro-level sociologist may study how large-scale historical events impact a society — in the past, in the present, and in the future. 

Sociologists compile their learnings about society and social interactions to make connections. This process is called sociological imagination.

WHAT IS SOCIOLOGICAL IMAGINATION?

Contemporary sociologist C. Wright Mill established the  sociological imagination  as a framework for connecting personal challenges and more significant social issues. Through the sociological imagination, sociologists develop a mindset to explain how these personal experiences, along with their challenges, impact the larger society in which we operate. Having a better understanding of the relationship between personal and public issues can help influence outcomes on every level.

When you begin to consider numerous situations or activities from views other than your own, you have entered into the domain of sociological imagination. For example, let’s look at homelessness. Some individuals believe homelessness is an individual problem — a person must have made poor choices and they became homeless. However, we know that’s not necessarily true — for many, homelessness may result from an unexpected illness, medical bills, or job loss. Through the sociological imagination, you’d understand homelessness as a consequence of many social factors that can impose burdens on individuals.

SOCIOLOGY TYPES

Sociology encompasses various subfields and areas of study that focus on understanding and analyzing different aspects of society. Here are some of the major types or branches of sociology:

• General Sociology : This is the broadest field of sociology that examines the overall structure and functioning of society, including social institutions, social inequality, social change, and social interactions.
• Social Stratification : This field focuses on the study of social class, social inequality, and the hierarchical division of society based on factors such as wealth, occupation, and social status.
• Sociology of Deviance : This branch explores behaviors and actions that deviate from societal norms and values, including the study of crime, social control, and the processes of labeling individuals as deviant.
• Sociology of Family : This field examines family structures, dynamics, and relationships, including topics such as marriage, parenting, gender roles, and the impact of family on individuals and society.
• Sociology of Education : This area of sociology explores the role of education in society, including educational institutions, access to education, socialization processes, and the impact of education on social mobility.
• Sociology of Religion : This branch focuses on the study of religious beliefs, practices, and institutions, as well as the role of religion in shaping social behavior, values, and social change.
• Sociology of Gender : This field examines the social construction of gender, gender roles, inequalities, and how gender intersects with other social categories such as race, class, and sexuality.
• Urban Sociology : This area of sociology analyzes the social structure, processes, and problems of urban areas, including urbanization, urban development, social interactions in cities, and the impact of urban living on individuals and communities.

These are just a few examples of the diverse areas within sociology. It is worth noting that many of these branches overlap and intersect, and sociologists often draw on multiple perspectives and theories to understand the complexities of social life.

5 EXAMPLES OF SOCIOLOGY IN EVERYDAY LIFE

Sociology is not an abstract concept. In everyday life and in our interactions, we see many examples that sociologists study. Here are five for you to consider:

1. Conflict Theory: Class or Social Inequalities

Among experts, much discussion and evaluation is occurring regarding social classes: how they are created, what fuels them, and what inequalities arise as a result. Social inequality is linked to an imbalance in the distribution of wealth and resources that can impact social standing, social class, and social life.

For example, sociologists study how race and gender contribute to social inequalities within and across our societies. Sociologists research the contributing elements that create gender wage-gaps, as well as how racial bias contributes to disproportionate police brutality against minority groups.

Sociologists evaluate social inequality in two primary categories:

• Inequality of conditions : the imbalanced and unequal distribution of wealth and income. For example, in the United States, 69.8 percent of the  country’s net worth  was held by the top 10 percent of the richest individuals, with the top one percent holding 32.1 percent in 2021. 
• Inequality of opportunities : the unequal availability of life opportunities, such as education, criminal justice, jobs, and health care. For example, the  Centers for Disease Control and Prevention  state that black women are more likely to experience a stillborn birth. A sociologist would study contributing factors that disproportionately impact black mothers, along with social inequalities, to draw conclusions and advocate for reform.

2. Symbolic Interactionism

Symbolic interactionism, another major sociological framework, aims to explain human behavior by evaluating the symbolic meanings individuals develop and build upon throughout their lives. In society, different objects, gestures, behaviors, and events may mean different things. 

Let’s look at an example — emojis. Now a standard in mobile communication, emojis can be interpreted differently to different groups. A smiling emoji could simply communicate being happy, but, it may also seem passive-aggressive.

Rainbows are another example of symbolism. Technically, a rainbow is a simple meteorological phenomenon. However, a rainbow may be used to express positive emotions, hope, and happiness. A rainbow is also a symbol for the LGBTQ+community as well, representing togetherness, unity, and pride.

3. Social Roles

“You are not acting your age.” “That was unprofessional behavior.” These are examples of assigning social roles throughout our interactions in different areas. Through the lens of socially-constructed gender roles, a sociologist may study why society expects women to behave in particular ways and how this contributes to larger issues, such as the wage gap.

The concept of roles focuses on predictable behavior — as human beings, predictability maintains stasis and prevents risk. Society “defines” these roles by creating predictable expectations of behavior — a person’s behavior should correspond to their social role. 

If a cashier tells a political joke to a customer, it may be perceived as offensive and inappropriate — it does not fit into the established societal rules for this role and this type of social interaction. However, if this cashier tells the same political joke to a friend, it may not be perceived in a potentially offensive or inappropriate manner with the customer, as this is a different social setting.

4. Emotional Expectations

Emotional expression is highly complex. It’s not simply a physiological response to stimuli; gender roles established in our society may influence how we express our emotions. For example, there’s an unwritten rule in our society that men don’t, or shouldn’t, cry — it’s not “masculine behavior.” On the other hand, women shouldn’t display aggression — it’s not “feminine behavior.” Through these expectations of behavior, individuals express emotions differently based on society’s gender norms. However, this contributes to a larger societal challenge – gender inequality.

5. Environmental Sociology

Today, climate change and environmental protection remain a high priority in our society. Our choices individually, nationally, and globally directly impact our world — environmental sociology aims to understand our interactions with our natural and created environments. 

For example, environmental-social movements advocate against companies that display a lack of environmental consciousness, either through animal testing, carbon footprint size, or destruction of protected lands and groups. An environmental sociologist may seek to understand why an organization may make these decisions, rather than consider alternate environmentally-sustainable methods instead. On a smaller scale, an environmental sociologist may study the relationship between energy and the environment. For example, electricity-fueled cars versus gas-fueled cars. An environmental sociologist may ask, “Are electric cars utilized among a particular set of individuals in a society?” “Are there factors that influence the affordability or availability of electric cars in relation to gas vehicles?” “Do cultural or societal constructs influence behavior or increased adoption of electric cars?” 

Overall, many examples of sociology appear in our everyday life. Sociology encompasses a broad study of social interactions, with many interesting career options. Additionally, sociology and psychology share both similarities and distinct differences that you may be interested in exploring. If you’re wondering whether to  major in sociology or psychology , we can help.

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Top 10 Study Tips to Study Like a Harvard Student

Adjusting to a demanding college workload might be a challenge, but these 10 study tips can help you stay prepared and focused.

Lian Parsons

The introduction to a new college curriculum can seem overwhelming, but optimizing your study habits can boost your confidence and success both in and out of the classroom. 

Transitioning from high school to the rigor of college studies can be overwhelming for many students, and finding the best way to study with a new course load can seem like a daunting process. 

Effective study methods work because they engage multiple ways of learning. As Jessie Schwab, psychologist and preceptor at the Harvard College Writing Program, points out, we tend to misjudge our own learning. Being able to recite memorized information is not the same as actually retaining it. 

“One thing we know from decades of cognitive science research is that learners are often bad judges of their own learning,” says Schwab. “Memorization seems like learning, but in reality, we probably haven’t deeply processed that information enough for us to remember it days—or even hours—later.”

Planning ahead and finding support along the way are essential to your success in college. This blog will offer study tips and strategies to help you survive (and thrive!) in your first college class. 

1. Don’t Cram! 

It might be tempting to leave all your studying for that big exam up until the last minute, but research suggests that cramming does not improve longer term learning. 

Students may perform well on a test for which they’ve crammed, but that doesn’t mean they’ve truly learned the material, says an article from the American Psychological Association . Instead of cramming, studies have shown that studying with the goal of long-term retention is best for learning overall.   

2. Plan Ahead—and Stick To It! 

Having a study plan with set goals can help you feel more prepared and can give you a roadmap to follow. Schwab said procrastination is one mistake that students often make when transitioning to a university-level course load. 

“Oftentimes, students are used to less intensive workloads in high school, so one of my biggest pieces of advice is don’t cram,” says Schwab. “Set yourself a study schedule ahead of time and stick to it.”

3. Ask for Help

You don’t have to struggle through difficult material on your own. Many students are not used to seeking help while in high school, but seeking extra support is common in college.

As our guide to pursuing a biology major explains, “Be proactive about identifying areas where you need assistance and seek out that assistance immediately. The longer you wait, the more difficult it becomes to catch up.”

There are multiple resources to help you, including your professors, tutors, and fellow classmates. Harvard’s Academic Resource Center offers academic coaching, workshops, peer tutoring, and accountability hours for students to keep you on track.  

4. Use the Buddy System 

Your fellow students are likely going through the same struggles that you are. Reach out to classmates and form a study group to go over material together, brainstorm, and to support each other through challenges.

Having other people to study with means you can explain the material to one another, quiz each other, and build a network you can rely on throughout the rest of the class—and beyond. 

5. Find Your Learning Style

It might take a bit of time (and trial and error!) to figure out what study methods work best for you. There are a variety of ways to test your knowledge beyond simply reviewing your notes or flashcards. 

Schwab recommends trying different strategies through the process of metacognition. Metacognition involves thinking about your own cognitive processes and can help you figure out what study methods are most effective for you. 

Schwab suggests practicing the following steps:

• Before you start to read a new chapter or watch a lecture, review what you already know about the topic and what you’re expecting to learn.
• As you read or listen, take additional notes about new information, such as related topics the material reminds you of or potential connections to other courses. Also note down questions you have.
• Afterward, try to summarize what you’ve learned and seek out answers to your remaining questions. 

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6. Take Breaks

The brain can only absorb so much information at a time. According to the National Institutes of Health , research has shown that taking breaks in between study sessions boosts retention. 

Studies have shown that wakeful rest plays just as important a role as practice in learning a new skill. Rest allows our brains to compress and consolidate memories of what we just practiced. 

Make sure that you are allowing enough time, relaxation, and sleep between study sessions so your brain will be refreshed and ready to accept new information.

7. Cultivate a Productive Space

Where you study can be just as important as how you study. 

Find a space that is free of distractions and has all the materials and supplies you need on hand. Eat a snack and have a water bottle close by so you’re properly fueled for your study session. 

8. Reward Yourself

Studying can be mentally and emotionally exhausting and keeping your stamina up can be challenging.

Studies have shown that giving yourself a reward during your work can increase the enjoyment and interest in a given task.

According to an article for Science Daily , studies have shown small rewards throughout the process can help keep up motivation, rather than saving it all until the end. 

Next time you finish a particularly challenging study session, treat yourself to an ice cream or  an episode of your favorite show.

9. Review, Review, Review

Practicing the information you’ve learned is the best way to retain information. 

Researchers Elizabeth and Robert Bjork have argued that “desirable difficulties” can enhance learning. For example, testing yourself with flashcards is a more difficult process than simply reading a textbook, but will lead to better long-term learning. 

“One common analogy is weightlifting—you have to actually “exercise those muscles” in order to ultimately strengthen your memories,” adds Schwab.

10. Set Specific Goals

Setting specific goals along the way of your studying journey can show how much progress you’ve made. Psychology Today recommends using the SMART method:

• Specific: Set specific goals with an actionable plan, such as “I will study every day between 2 and 4 p.m. at the library.”  
• Measurable: Plan to study a certain number of hours or raise your exam score by a certain percent to give you a measurable benchmark.
• Realistic: It’s important that your goals be realistic so you don’t get discouraged. For example, if you currently study two hours per week, increase the time you spend to three or four hours rather than 10.
• Time-specific: Keep your goals consistent with your academic calendar and your other responsibilities.

Using a handful of these study tips can ensure that you’re getting the most out of the material in your classes and help set you up for success for the rest of your academic career and beyond. 

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About the Author

Lian Parsons is a Boston-based writer and journalist. She is currently a digital content producer at Harvard’s Division of Continuing Education. Her bylines can be found at the Harvard Gazette, Boston Art Review, Radcliffe Magazine, Experience Magazine, and iPondr.

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• USC Libraries
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Organizing Your Social Sciences Research Paper

• Reading Research Effectively
• Purpose of Guide
• Design Flaws to Avoid
• Independent and Dependent Variables
• Glossary of Research Terms
• Narrowing a Topic Idea
• Broadening a Topic Idea
• Extending the Timeliness of a Topic Idea
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• The Research Problem/Question
• Theoretical Framework
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• Primary Sources
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• Tiertiary Sources
• Scholarly vs. Popular Publications
• Qualitative Methods
• Quantitative Methods
• Insiderness
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• Common Grammar Mistakes
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Reading a Scholarly Article or Research Paper

Identifying a research problem to investigate requires a preliminary search for and critical review of the literature in order to gain an understanding about how scholars have examined a topic. Scholars rarely structure research studies in a way that can be followed like a story; they are complex and detail-intensive and often written in a descriptive and conclusive narrative form. However, in the social and behavioral sciences, journal articles and stand-alone research reports are generally organized in a consistent format that makes it easier to compare and contrast studies and interpret their findings.

General Reading Strategies

W hen you first read an article or research paper, focus on asking specific questions about each section. This strategy can help with overall comprehension and with understanding how the content relates [or does not relate] to the problem you want to investigate. As you review more and more studies, the process of understanding and critically evaluating the research will become easier because the content of what you review will begin to coalescence around common themes and patterns of analysis. Below are recommendations on how to read each section of a research paper effectively. Note that the sections to read are out of order from how you will find them organized in a journal article or research paper.

1.  Abstract

The abstract summarizes the background, methods, results, discussion, and conclusions of a scholarly article or research paper. Use the abstract to filter out sources that may have appeared useful when you began searching for information but, in reality, are not relevant. Questions to consider when reading the abstract are:

• Is this study related to my question or area of research?
• What is this study about and why is it being done ?
• What is the working hypothesis or underlying thesis?
• What is the primary finding of the study?
• Are there words or terminology that I can use to either narrow or broaden the parameters of my search for more information?

2.  Introduction

If, after reading the abstract, you believe the paper may be useful, focus on examining the research problem and identifying the questions the author is trying to address. This information is usually located within the first few paragraphs of the introduction or in the concluding paragraph. Look for information about how and in what way this relates to what you are investigating. In addition to the research problem, the introduction should provide the main argument and theoretical framework of the study and, in the last paragraphs of the introduction, describe what the author(s) intend to accomplish. Questions to consider when reading the introduction include:

• What is this study trying to prove or disprove?
• What is the author(s) trying to test or demonstrate?
• What do we already know about this topic and what gaps does this study try to fill or contribute a new understanding to the research problem?
• Why should I care about what is being investigated?
• Will this study tell me anything new related to the research problem I am investigating?

3.  Literature Review

The literature review describes and critically evaluates what is already known about a topic. Read the literature review to obtain a big picture perspective about how the topic has been studied and to begin the process of seeing where your potential study fits within the domain of prior research. Questions to consider when reading the literature review include:

• W hat other research has been conducted about this topic and what are the main themes that have emerged?
• What does prior research reveal about what is already known about the topic and what remains to be discovered?
• What have been the most important past findings about the research problem?
• How has prior research led the author(s) to conduct this particular study?
• Is there any prior research that is unique or groundbreaking?
• Are there any studies I could use as a model for designing and organizing my own study?

4.  Discussion/Conclusion

The discussion and conclusion are usually the last two sections of text in a scholarly article or research report. They reveal how the author(s) interpreted the findings of their research and presented recommendations or courses of action based on those findings. Often in the conclusion, the author(s) highlight recommendations for further research that can be used to develop your own study. Questions to consider when reading the discussion and conclusion sections include:

• What is the overall meaning of the study and why is this important? [i.e., how have the author(s) addressed the " So What? " question].
• What do you find to be the most important ways that the findings have been interpreted?
• What are the weaknesses in their argument?
• Do you believe conclusions about the significance of the study and its findings are valid?
• What limitations of the study do the author(s) describe and how might this help formulate my own research?
• Does the conclusion contain any recommendations for future research?

5.  Methods/Methodology

The methods section describes the materials, techniques, and procedures for gathering information used to examine the research problem. If what you have read so far closely supports your understanding of the topic, then move on to examining how the author(s) gathered information during the research process. Questions to consider when reading the methods section include:

• Did the study use qualitative [based on interviews, observations, content analysis], quantitative [based on statistical analysis], or a mixed-methods approach to examining the research problem?
• What was the type of information or data used?
• Could this method of analysis be repeated and can I adopt the same approach?
• Is enough information available to repeat the study or should new data be found to expand or improve understanding of the research problem?

6.  Results

After reading the above sections, you should have a clear understanding of the general findings of the study. Therefore, read the results section to identify how key findings were discussed in relation to the research problem. If any non-textual elements [e.g., graphs, charts, tables, etc.] are confusing, focus on the explanations about them in the text. Questions to consider when reading the results section include:

• W hat did the author(s) find and how did they find it?
• Does the author(s) highlight any findings as most significant?
• Are the results presented in a factual and unbiased way?
• Does the analysis of results in the discussion section agree with how the results are presented?
• Is all the data present and did the author(s) adequately address gaps?
• What conclusions do you formulate from this data and does it match with the author's conclusions?

7.  References

The references list the sources used by the author(s) to document what prior research and information was used when conducting the study. After reviewing the article or research paper, use the references to identify additional sources of information on the topic and to examine critically how these sources supported the overall research agenda. Questions to consider when reading the references include:

• Do the sources cited by the author(s) reflect a diversity of disciplinary viewpoints, i.e., are the sources all from a particular field of study or do the sources reflect multiple areas of study?
• Are there any unique or interesting sources that could be incorporated into my study?
• What other authors are respected in this field, i.e., who has multiple works cited or is cited most often by others?
• What other research should I review to clarify any remaining issues or that I need more information about?

NOTE:   A final strategy in reviewing research is to copy and paste the title of the source [journal article, book, research report] into Google Scholar . If it appears, look for a "cited by" reference followed by a hyperlinked number under the record [e.g., Cited by 45]. This number indicates how many times the study has been subsequently cited in other, more recently published works. This strategy, known as citation tracking, can be an effective means of expanding your review of pertinent literature based on a study you have found useful and how scholars have cited it. The same strategies described above can be applied to reading articles you find in the list of cited by references.

Reading Tip

Specific Reading Strategies

Effectively reading scholarly research is an acquired skill that involves attention to detail and an ability to comprehend complex ideas, data, and theoretical concepts in a way that applies logically to the research problem you are investigating. Here are some specific reading strategies to consider.

As You are Reading

• Focus on information that is most relevant to the research problem; skim over the other parts.
• As noted above, read content out of order! This isn't a novel; you want to start with the spoiler to quickly assess the relevance of the study.
• Think critically about what you read and seek to build your own arguments; not everything may be entirely valid, examined effectively, or thoroughly investigated.
• Look up the definitions of unfamiliar words, concepts, or terminology. A good scholarly source is Credo Reference .

Taking notes as you read will save time when you go back to examine your sources. Here are some suggestions:

• Mark or highlight important text as you read [e.g., you can use the highlight text  feature in a PDF document]
• Take notes in the margins [e.g., Adobe Reader offers pop-up sticky notes].
• Highlight important quotations; consider using different highlighting colors to differentiate between quotes and other types of important text.
• Summarize key points about the study at the end of the paper. To save time, these can be in the form of a concise bulleted list of statements [e.g., intro provides useful historical background; lit review has important sources; good conclusions].

Write down thoughts that come to mind that may help clarify your understanding of the research problem. Here are some examples of questions to ask yourself:

• Do I understand all of the terminology and key concepts?
• Do I understand the parts of this study most relevant to my topic?
• What specific problem does the research address and why is it important?
• Are there any issues or perspectives the author(s) did not consider?
• Do I have any reason to question the validity or reliability of this research?
• How do the findings relate to my research interests and to other works which I have read?

Adapted from text originally created by Holly Burt, Behavioral Sciences Librarian, USC Libraries, April 2018.

Another Reading Tip

When is it Important to Read the Entire Article or Research Paper

Laubepin argues, "Very few articles in a field are so important that every word needs to be read carefully." * However, this implies that some studies are worth reading carefully if they directly relate to understanding the research problem. As arduous as it may seem, there are valid reasons for reading a study from beginning to end. Here are some examples:

• Studies Published Very Recently .  The author(s) of a recent, well written study will provide a survey of the most important or impactful prior research in the literature review section. This can establish an understanding of how scholars in the past addressed the research problem. In addition, the most recently published sources will highlight what is known and what gaps in understanding currently exist about a topic, usually in the form of the need for further research in the conclusion .
• Surveys of the Research Problem .  Some papers provide a comprehensive analytical overview of the research problem. Reading this type of study can help you understand underlying issues and discover why scholars have chosen to investigate the topic. This is particularly important if the study was published recently because the author(s) should cite all or most of the important prior research on the topic. Note that, if it is a long-standing problem, there may be studies that specifically review the literature to identify gaps that remain. These studies often include the word "review" in their title [e.g., Hügel, Stephan, and Anna R. Davies. "Public Participation, Engagement, and Climate Change Adaptation: A Review of the Research Literature." Wiley Interdisciplinary Reviews: Climate Change 11 (July-August 2020): https://doi.org/10.1002/ wcc.645].
• Highly Cited .  If you keep coming across the same citation to a study while you are reviewing the literature, this implies it was foundational in establishing an understanding of the research problem or the study had a significant impact within the literature [either positive or negative]. Carefully reading a highly cited source can help you understand how the topic emerged and how it motivated scholars to further investigate the problem. It also could be a study you need to cite as foundational in your own paper to demonstrate to the reader that you understand the roots of the problem.
• Historical Overview .  Knowing the historical background of a research problem may not be the focus of your analysis. Nevertheless, carefully reading a study that provides a thorough description and analysis of the history behind an event, issue, or phenomenon can add important context to understanding the topic and what aspect of the problem you may want to examine further.
• Innovative Methodological Design .  Some studies are significant and should be read in their entirety because the author(s) designed a unique or innovative approach to researching the problem. This may justify reading the entire study because it can motivate you to think creatively about also pursuing an alternative or non-traditional approach to examining your topic of interest. These types of studies are generally easy to identify because they are often cited in others works because of their unique approach to examining the research problem.
• Cross-disciplinary Approach .  R eviewing studies produced outside of your discipline is an essential component of investigating research problems in the social and behavioral sciences. Consider reading a study that was conducted by author(s) based in a different discipline [e.g., an anthropologist studying political cultures; a study of hiring practices in companies published in a sociology journal]. This approach can generate a new understanding or a unique perspective about the topic . If you are not sure how to search for studies published in a discipline outside of your major or of the course you are taking, contact a librarian for assistance.

* Laubepin, Frederique. How to Read (and Understand) a Social Science Journal Article . Inter-University Consortium for Political and Social Research (ISPSR), 2013

Shon, Phillip Chong Ho. How to Read Journal Articles in the Social Sciences: A Very Practical Guide for Students . 2nd edition. Thousand Oaks, CA: Sage, 2015; Lockhart, Tara, and Mary Soliday. "The Critical Place of Reading in Writing Transfer (and Beyond): A Report of Student Experiences." Pedagogy 16 (2016): 23-37; Maguire, Moira, Ann Everitt Reynolds, and Brid Delahunt. "Reading to Be: The Role of Academic Reading in Emergent Academic and Professional Student Identities." Journal of University Teaching and Learning Practice 17 (2020): 5-12.

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