a scientific hypothesis is best described as an educated guess

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1.6: Hypothesis, Theories, and Laws

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Learning Objectives

Describe the difference between hypothesis and theory as scientific terms.
Describe the difference between a theory and scientific law.

Although many have taken science classes throughout the course of their studies, people often have incorrect or misleading ideas about some of the most important and basic principles in science. Most students have heard of hypotheses, theories, and laws, but what do these terms really mean? Prior to reading this section, consider what you have learned about these terms before. What do these terms mean to you? What do you read that contradicts or supports what you thought?

What is a Fact?

A fact is a basic statement established by experiment or observation. All facts are true under the specific conditions of the observation.

What is a Hypothesis?

One of the most common terms used in science classes is a "hypothesis". The word can have many different definitions, depending on the context in which it is being used:

An educated guess: a scientific hypothesis provides a suggested solution based on evidence.
Prediction: if you have ever carried out a science experiment, you probably made this type of hypothesis when you predicted the outcome of your experiment.
Tentative or proposed explanation: hypotheses can be suggestions about why something is observed. In order for it to be scientific, however, a scientist must be able to test the explanation to see if it works and if it is able to correctly predict what will happen in a situation. For example, "if my hypothesis is correct, we should see ___ result when we perform ___ test."

A hypothesis is very tentative; it can be easily changed.

What is a Theory?

The United States National Academy of Sciences describes what a theory is as follows:

"Some scientific explanations are so well established that no new evidence is likely to alter them. The explanation becomes a scientific theory. In everyday language a theory means a hunch or speculation. Not so in science. In science, the word theory refers to a comprehensive explanation of an important feature of nature supported by facts gathered over time. Theories also allow scientists to make predictions about as yet unobserved phenomena."

"A scientific theory is a well-substantiated explanation of some aspect of the natural world, based on a body of facts that have been repeatedly confirmed through observation and experimentation. Such fact-supported theories are not "guesses" but reliable accounts of the real world. The theory of biological evolution is more than "just a theory." It is as factual an explanation of the universe as the atomic theory of matter (stating that everything is made of atoms) or the germ theory of disease (which states that many diseases are caused by germs). Our understanding of gravity is still a work in progress. But the phenomenon of gravity, like evolution, is an accepted fact.

Note some key features of theories that are important to understand from this description:

Theories are explanations of natural phenomena. They aren't predictions (although we may use theories to make predictions). They are explanations as to why we observe something.
Theories aren't likely to change. They have a large amount of support and are able to satisfactorily explain numerous observations. Theories can, indeed, be facts. Theories can change, but it is a long and difficult process. In order for a theory to change, there must be many observations or pieces of evidence that the theory cannot explain.
Theories are not guesses. The phrase "just a theory" has no room in science. To be a scientific theory carries a lot of weight; it is not just one person's idea about something

Theories aren't likely to change.

What is a Law?

Scientific laws are similar to scientific theories in that they are principles that can be used to predict the behavior of the natural world. Both scientific laws and scientific theories are typically well-supported by observations and/or experimental evidence. Usually scientific laws refer to rules for how nature will behave under certain conditions, frequently written as an equation. Scientific theories are more overarching explanations of how nature works and why it exhibits certain characteristics. As a comparison, theories explain why we observe what we do and laws describe what happens.

For example, around the year 1800, Jacques Charles and other scientists were working with gases to, among other reasons, improve the design of the hot air balloon. These scientists found, after many, many tests, that certain patterns existed in the observations on gas behavior. If the temperature of the gas is increased, the volume of the gas increased. This is known as a natural law. A law is a relationship that exists between variables in a group of data. Laws describe the patterns we see in large amounts of data, but do not describe why the patterns exist.

What is a Belief?

A belief is a statement that is not scientifically provable. Beliefs may or may not be incorrect; they just are outside the realm of science to explore.

Laws vs. Theories

A common misconception is that scientific theories are rudimentary ideas that will eventually graduate into scientific laws when enough data and evidence has accumulated. A theory does not change into a scientific law with the accumulation of new or better evidence. Remember, theories are explanations and laws are patterns we see in large amounts of data, frequently written as an equation. A theory will always remain a theory; a law will always remain a law.

Video \(\PageIndex{1}\): What’s the difference between a scientific law and theory?

A hypothesis is a tentative explanation that can be tested by further investigation.
A theory is a well-supported explanation of observations.
A scientific law is a statement that summarizes the relationship between variables.
An experiment is a controlled method of testing a hypothesis.

Contributions & Attributions

Marisa Alviar-Agnew ( Sacramento City College )

Henry Agnew (UC Davis)

What is a scientific hypothesis?

It's the initial building block in the scientific method.

A girl looks at plants in a test tube for a science experiment. What's her scientific hypothesis?

Hypothesis basics

What makes a hypothesis testable.

Types of hypotheses
Hypothesis versus theory

Additional resources

Bibliography.

A scientific hypothesis is a tentative, testable explanation for a phenomenon in the natural world. It's the initial building block in the scientific method . Many describe it as an "educated guess" based on prior knowledge and observation. While this is true, a hypothesis is more informed than a guess. While an "educated guess" suggests a random prediction based on a person's expertise, developing a hypothesis requires active observation and background research.

The basic idea of a hypothesis is that there is no predetermined outcome. For a solution to be termed a scientific hypothesis, it has to be an idea that can be supported or refuted through carefully crafted experimentation or observation. This concept, called falsifiability and testability, was advanced in the mid-20th century by Austrian-British philosopher Karl Popper in his famous book "The Logic of Scientific Discovery" (Routledge, 1959).

A key function of a hypothesis is to derive predictions about the results of future experiments and then perform those experiments to see whether they support the predictions.

A hypothesis is usually written in the form of an if-then statement, which gives a possibility (if) and explains what may happen because of the possibility (then). The statement could also include "may," according to California State University, Bakersfield .

Here are some examples of hypothesis statements:

If garlic repels fleas, then a dog that is given garlic every day will not get fleas.
If sugar causes cavities, then people who eat a lot of candy may be more prone to cavities.
If ultraviolet light can damage the eyes, then maybe this light can cause blindness.

A useful hypothesis should be testable and falsifiable. That means that it should be possible to prove it wrong. A theory that can't be proved wrong is nonscientific, according to Karl Popper's 1963 book " Conjectures and Refutations ."

An example of an untestable statement is, "Dogs are better than cats." That's because the definition of "better" is vague and subjective. However, an untestable statement can be reworded to make it testable. For example, the previous statement could be changed to this: "Owning a dog is associated with higher levels of physical fitness than owning a cat." With this statement, the researcher can take measures of physical fitness from dog and cat owners and compare the two.

Types of scientific hypotheses

Elementary-age students study alternative energy using homemade windmills during public school science class.

In an experiment, researchers generally state their hypotheses in two ways. The null hypothesis predicts that there will be no relationship between the variables tested, or no difference between the experimental groups. The alternative hypothesis predicts the opposite: that there will be a difference between the experimental groups. This is usually the hypothesis scientists are most interested in, according to the University of Miami .

For example, a null hypothesis might state, "There will be no difference in the rate of muscle growth between people who take a protein supplement and people who don't." The alternative hypothesis would state, "There will be a difference in the rate of muscle growth between people who take a protein supplement and people who don't."

If the results of the experiment show a relationship between the variables, then the null hypothesis has been rejected in favor of the alternative hypothesis, according to the book " Research Methods in Psychology " (BCcampus, 2015).

There are other ways to describe an alternative hypothesis. The alternative hypothesis above does not specify a direction of the effect, only that there will be a difference between the two groups. That type of prediction is called a two-tailed hypothesis. If a hypothesis specifies a certain direction — for example, that people who take a protein supplement will gain more muscle than people who don't — it is called a one-tailed hypothesis, according to William M. K. Trochim , a professor of Policy Analysis and Management at Cornell University.

Sometimes, errors take place during an experiment. These errors can happen in one of two ways. A type I error is when the null hypothesis is rejected when it is true. This is also known as a false positive. A type II error occurs when the null hypothesis is not rejected when it is false. This is also known as a false negative, according to the University of California, Berkeley .

A hypothesis can be rejected or modified, but it can never be proved correct 100% of the time. For example, a scientist can form a hypothesis stating that if a certain type of tomato has a gene for red pigment, that type of tomato will be red. During research, the scientist then finds that each tomato of this type is red. Though the findings confirm the hypothesis, there may be a tomato of that type somewhere in the world that isn't red. Thus, the hypothesis is true, but it may not be true 100% of the time.

Scientific theory vs. scientific hypothesis

The best hypotheses are simple. They deal with a relatively narrow set of phenomena. But theories are broader; they generally combine multiple hypotheses into a general explanation for a wide range of phenomena, according to the University of California, Berkeley . For example, a hypothesis might state, "If animals adapt to suit their environments, then birds that live on islands with lots of seeds to eat will have differently shaped beaks than birds that live on islands with lots of insects to eat." After testing many hypotheses like these, Charles Darwin formulated an overarching theory: the theory of evolution by natural selection.

"Theories are the ways that we make sense of what we observe in the natural world," Tanner said. "Theories are structures of ideas that explain and interpret facts."

Read more about writing a hypothesis, from the American Medical Writers Association.
Find out why a hypothesis isn't always necessary in science, from The American Biology Teacher.
Learn about null and alternative hypotheses, from Prof. Essa on YouTube .

Encyclopedia Britannica. Scientific Hypothesis. Jan. 13, 2022. https://www.britannica.com/science/scientific-hypothesis

Karl Popper, "The Logic of Scientific Discovery," Routledge, 1959.

California State University, Bakersfield, "Formatting a testable hypothesis." https://www.csub.edu/~ddodenhoff/Bio100/Bio100sp04/formattingahypothesis.htm

Karl Popper, "Conjectures and Refutations," Routledge, 1963.

Price, P., Jhangiani, R., & Chiang, I., "Research Methods of Psychology — 2nd Canadian Edition," BCcampus, 2015.‌

University of Miami, "The Scientific Method" http://www.bio.miami.edu/dana/161/evolution/161app1_scimethod.pdf

William M.K. Trochim, "Research Methods Knowledge Base," https://conjointly.com/kb/hypotheses-explained/

University of California, Berkeley, "Multiple Hypothesis Testing and False Discovery Rate" https://www.stat.berkeley.edu/~hhuang/STAT141/Lecture-FDR.pdf

University of California, Berkeley, "Science at multiple levels" https://undsci.berkeley.edu/article/0_0_0/howscienceworks_19

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1.2 The Scientific Methods

Section learning objectives.

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

Explain how the methods of science are used to make scientific discoveries
Define a scientific model and describe examples of physical and mathematical models used in physics
Compare and contrast hypothesis, theory, and law

Teacher Support

The learning objectives in this section will help your students master the following standards:

(A) know the definition of science and understand that it has limitations, as specified in subsection (b)(2) of this section;
(B) know that scientific hypotheses are tentative and testable statements that must be capable of being supported or not supported by observational evidence. Hypotheses of durable explanatory power which have been tested over a wide variety of conditions are incorporated into theories;
(C) know that scientific theories are based on natural and physical phenomena and are capable of being tested by multiple independent researchers. Unlike hypotheses, scientific theories are well-established and highly-reliable explanations, but may be subject to change as new areas of science and new technologies are developed;
(D) distinguish between scientific hypotheses and scientific theories.

Section Key Terms

[OL] Pre-assessment for this section could involve students sharing or writing down an anecdote about when they used the methods of science. Then, students could label their thought processes in their anecdote with the appropriate scientific methods. The class could also discuss their definitions of theory and law, both outside and within the context of science.

[OL] It should be noted and possibly mentioned that a scientist , as mentioned in this section, does not necessarily mean a trained scientist. It could be anyone using methods of science.

Scientific Methods

Scientists often plan and carry out investigations to answer questions about the universe around us. These investigations may lead to natural laws. Such laws are intrinsic to the universe, meaning that humans did not create them and cannot change them. We can only discover and understand them. Their discovery is a very human endeavor, with all the elements of mystery, imagination, struggle, triumph, and disappointment inherent in any creative effort. The cornerstone of discovering natural laws is observation. Science must describe the universe as it is, not as we imagine or wish it to be.

We all are curious to some extent. We look around, make generalizations, and try to understand what we see. For example, we look up and wonder whether one type of cloud signals an oncoming storm. As we become serious about exploring nature, we become more organized and formal in collecting and analyzing data. We attempt greater precision, perform controlled experiments (if we can), and write down ideas about how data may be organized. We then formulate models, theories, and laws based on the data we have collected, and communicate those results with others. This, in a nutshell, describes the scientific method that scientists employ to decide scientific issues on the basis of evidence from observation and experiment.

An investigation often begins with a scientist making an observation . The scientist observes a pattern or trend within the natural world. Observation may generate questions that the scientist wishes to answer. Next, the scientist may perform some research about the topic and devise a hypothesis . A hypothesis is a testable statement that describes how something in the natural world works. In essence, a hypothesis is an educated guess that explains something about an observation.

[OL] An educated guess is used throughout this section in describing a hypothesis to combat the tendency to think of a theory as an educated guess.

Scientists may test the hypothesis by performing an experiment . During an experiment, the scientist collects data that will help them learn about the phenomenon they are studying. Then the scientists analyze the results of the experiment (that is, the data), often using statistical, mathematical, and/or graphical methods. From the data analysis, they draw conclusions. They may conclude that their experiment either supports or rejects their hypothesis. If the hypothesis is supported, the scientist usually goes on to test another hypothesis related to the first. If their hypothesis is rejected, they will often then test a new and different hypothesis in their effort to learn more about whatever they are studying.

Scientific processes can be applied to many situations. Let’s say that you try to turn on your car, but it will not start. You have just made an observation! You ask yourself, "Why won’t my car start?" You can now use scientific processes to answer this question. First, you generate a hypothesis such as, "The car won’t start because it has no gasoline in the gas tank." To test this hypothesis, you put gasoline in the car and try to start it again. If the car starts, then your hypothesis is supported by the experiment. If the car does not start, then your hypothesis is rejected. You will then need to think up a new hypothesis to test such as, "My car won’t start because the fuel pump is broken." Hopefully, your investigations lead you to discover why the car won’t start and enable you to fix it.

A model is a representation of something that is often too difficult (or impossible) to study directly. Models can take the form of physical models, equations, computer programs, or simulations—computer graphics/animations. Models are tools that are especially useful in modern physics because they let us visualize phenomena that we normally cannot observe with our senses, such as very small objects or objects that move at high speeds. For example, we can understand the structure of an atom using models, without seeing an atom with our own eyes. Although images of single atoms are now possible, these images are extremely difficult to achieve and are only possible due to the success of our models. The existence of these images is a consequence rather than a source of our understanding of atoms. Models are always approximate, so they are simpler to consider than the real situation; the more complete a model is, the more complicated it must be. Models put the intangible or the extremely complex into human terms that we can visualize, discuss, and hypothesize about.

Scientific models are constructed based on the results of previous experiments. Even still, models often only describe a phenomenon partially or in a few limited situations. Some phenomena are so complex that they may be impossible to model them in their entirety, even using computers. An example is the electron cloud model of the atom in which electrons are moving around the atom’s center in distinct clouds ( Figure 1.12 ), that represent the likelihood of finding an electron in different places. This model helps us to visualize the structure of an atom. However, it does not show us exactly where an electron will be within its cloud at any one particular time.

As mentioned previously, physicists use a variety of models including equations, physical models, computer simulations, etc. For example, three-dimensional models are often commonly used in chemistry and physics to model molecules. Properties other than appearance or location are usually modelled using mathematics, where functions are used to show how these properties relate to one another. Processes such as the formation of a star or the planets, can also be modelled using computer simulations. Once a simulation is correctly programmed based on actual experimental data, the simulation can allow us to view processes that happened in the past or happen too quickly or slowly for us to observe directly. In addition, scientists can also run virtual experiments using computer-based models. In a model of planet formation, for example, the scientist could alter the amount or type of rocks present in space and see how it affects planet formation.

Scientists use models and experimental results to construct explanations of observations or design solutions to problems. For example, one way to make a car more fuel efficient is to reduce the friction or drag caused by air flowing around the moving car. This can be done by designing the body shape of the car to be more aerodynamic, such as by using rounded corners instead of sharp ones. Engineers can then construct physical models of the car body, place them in a wind tunnel, and examine the flow of air around the model. This can also be done mathematically in a computer simulation. The air flow pattern can be analyzed for regions smooth air flow and for eddies that indicate drag. The model of the car body may have to be altered slightly to produce the smoothest pattern of air flow (i.e., the least drag). The pattern with the least drag may be the solution to increasing fuel efficiency of the car. This solution might then be incorporated into the car design.

Using Models and the Scientific Processes

Be sure to secure loose items before opening the window or door.

In this activity, you will learn about scientific models by making a model of how air flows through your classroom or a room in your house.

One room with at least one window or door that can be opened
Work with a group of four, as directed by your teacher. Close all of the windows and doors in the room you are working in. Your teacher may assign you a specific window or door to study.
Before opening any windows or doors, draw a to-scale diagram of your room. First, measure the length and width of your room using the tape measure. Then, transform the measurement using a scale that could fit on your paper, such as 5 centimeters = 1 meter.
Your teacher will assign you a specific window or door to study air flow. On your diagram, add arrows showing your hypothesis (before opening any windows or doors) of how air will flow through the room when your assigned window or door is opened. Use pencil so that you can easily make changes to your diagram.
On your diagram, mark four locations where you would like to test air flow in your room. To test for airflow, hold a strip of single ply tissue paper between the thumb and index finger. Note the direction that the paper moves when exposed to the airflow. Then, for each location, predict which way the paper will move if your air flow diagram is correct.
Now, each member of your group will stand in one of the four selected areas. Each member will test the airflow Agree upon an approximate height at which everyone will hold their papers.
When you teacher tells you to, open your assigned window and/or door. Each person should note the direction that their paper points immediately after the window or door was opened. Record your results on your diagram.
Did the airflow test data support or refute the hypothetical model of air flow shown in your diagram? Why or why not? Correct your model based on your experimental evidence.
With your group, discuss how accurate your model is. What limitations did it have? Write down the limitations that your group agreed upon.
Yes, you could use your model to predict air flow through a new window. The earlier experiment of air flow would help you model the system more accurately.
Yes, you could use your model to predict air flow through a new window. The earlier experiment of air flow is not useful for modeling the new system.
No, you cannot model a system to predict the air flow through a new window. The earlier experiment of air flow would help you model the system more accurately.
No, you cannot model a system to predict the air flow through a new window. The earlier experiment of air flow is not useful for modeling the new system.

This Snap Lab! has students construct a model of how air flows in their classroom. Each group of four students will create a model of air flow in their classroom using a scale drawing of the room. Then, the groups will test the validity of their model by placing weathervanes that they have constructed around the room and opening a window or door. By observing the weather vanes, students will see how air actually flows through the room from a specific window or door. Students will then correct their model based on their experimental evidence. The following material list is given per group:

One room with at least one window or door that can be opened (An optimal configuration would be one window or door per group.)
Several pieces of construction paper (at least four per group)
Strips of single ply tissue paper
One tape measure (long enough to measure the dimensions of the room)
Group size can vary depending on the number of windows/doors available and the number of students in the class.
The room dimensions could be provided by the teacher. Also, students may need a brief introduction in how to make a drawing to scale.
This is another opportunity to discuss controlled experiments in terms of why the students should hold the strips of tissue paper at the same height and in the same way. One student could also serve as a control and stand far away from the window/door or in another area that will not receive air flow from the window/door.
You will probably need to coordinate this when multiple windows or doors are used. Only one window or door should be opened at a time for best results. Between openings, allow a short period (5 minutes) when all windows and doors are closed, if possible.

Answers to the Grasp Check will vary, but the air flow in the new window or door should be based on what the students observed in their experiment.

Scientific Laws and Theories

A scientific law is a description of a pattern in nature that is true in all circumstances that have been studied. That is, physical laws are meant to be universal , meaning that they apply throughout the known universe. Laws are often also concise, whereas theories are more complicated. A law can be expressed in the form of a single sentence or mathematical equation. For example, Newton’s second law of motion , which relates the motion of an object to the force applied ( F ), the mass of the object ( m ), and the object’s acceleration ( a ), is simply stated using the equation

Scientific ideas and explanations that are true in many, but not all situations in the universe are usually called principles . An example is Pascal’s principle , which explains properties of liquids, but not solids or gases. However, the distinction between laws and principles is sometimes not carefully made in science.

A theory is an explanation for patterns in nature that is supported by much scientific evidence and verified multiple times by multiple researchers. While many people confuse theories with educated guesses or hypotheses, theories have withstood more rigorous testing and verification than hypotheses.

[OL] Explain to students that in informal, everyday English the word theory can be used to describe an idea that is possibly true but that has not been proven to be true. This use of the word theory often leads people to think that scientific theories are nothing more than educated guesses. This is not just a misconception among students, but among the general public as well.

As a closing idea about scientific processes, we want to point out that scientific laws and theories, even those that have been supported by experiments for centuries, can still be changed by new discoveries. This is especially true when new technologies emerge that allow us to observe things that were formerly unobservable. Imagine how viewing previously invisible objects with a microscope or viewing Earth for the first time from space may have instantly changed our scientific theories and laws! What discoveries still await us in the future? The constant retesting and perfecting of our scientific laws and theories allows our knowledge of nature to progress. For this reason, many scientists are reluctant to say that their studies prove anything. By saying support instead of prove , it keeps the door open for future discoveries, even if they won’t occur for centuries or even millennia.

[OL] With regard to scientists avoiding using the word prove , the general public knows that science has proven certain things such as that the heart pumps blood and the Earth is round. However, scientists should shy away from using prove because it is impossible to test every single instance and every set of conditions in a system to absolutely prove anything. Using support or similar terminology leaves the door open for further discovery.

Check Your Understanding

Models are simpler to analyze.
Models give more accurate results.
Models provide more reliable predictions.
Models do not require any computer calculations.
They are the same.
A hypothesis has been thoroughly tested and found to be true.
A hypothesis is a tentative assumption based on what is already known.
A hypothesis is a broad explanation firmly supported by evidence.
A scientific model is a representation of something that can be easily studied directly. It is useful for studying things that can be easily analyzed by humans.
A scientific model is a representation of something that is often too difficult to study directly. It is useful for studying a complex system or systems that humans cannot observe directly.
A scientific model is a representation of scientific equipment. It is useful for studying working principles of scientific equipment.
A scientific model is a representation of a laboratory where experiments are performed. It is useful for studying requirements needed inside the laboratory.
The hypothesis must be validated by scientific experiments.
The hypothesis must not include any physical quantity.
The hypothesis must be a short and concise statement.
The hypothesis must apply to all the situations in the universe.
A scientific theory is an explanation of natural phenomena that is supported by evidence.
A scientific theory is an explanation of natural phenomena without the support of evidence.
A scientific theory is an educated guess about the natural phenomena occurring in nature.
A scientific theory is an uneducated guess about natural phenomena occurring in nature.
A hypothesis is an explanation of the natural world with experimental support, while a scientific theory is an educated guess about a natural phenomenon.
A hypothesis is an educated guess about natural phenomenon, while a scientific theory is an explanation of natural world with experimental support.
A hypothesis is experimental evidence of a natural phenomenon, while a scientific theory is an explanation of the natural world with experimental support.
A hypothesis is an explanation of the natural world with experimental support, while a scientific theory is experimental evidence of a natural phenomenon.

Use the Check Your Understanding questions to assess students’ achievement of the section’s learning objectives. If students are struggling with a specific objective, the Check Your Understanding will help identify which objective and direct students to the relevant content.

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Biology library

Course: biology library > unit 1, the scientific method.

Controlled experiments
The scientific method and experimental design

Introduction

Make an observation.
Ask a question.
Form a hypothesis , or testable explanation.
Make a prediction based on the hypothesis.
Test the prediction.
Iterate: use the results to make new hypotheses or predictions.

Scientific method example: Failure to toast

1. make an observation..

Observation: the toaster won't toast.

2. Ask a question.

Question: Why won't my toaster toast?

3. Propose a hypothesis.

Hypothesis: Maybe the outlet is broken.

4. Make predictions.

Prediction: If I plug the toaster into a different outlet, then it will toast the bread.

5. Test the predictions.

Test of prediction: Plug the toaster into a different outlet and try again.
If the toaster does toast, then the hypothesis is supported—likely correct.
If the toaster doesn't toast, then the hypothesis is not supported—likely wrong.

Logical possibility

Practical possibility, building a body of evidence, 6. iterate..

Iteration time!
If the hypothesis was supported, we might do additional tests to confirm it, or revise it to be more specific. For instance, we might investigate why the outlet is broken.
If the hypothesis was not supported, we would come up with a new hypothesis. For instance, the next hypothesis might be that there's a broken wire in the toaster.

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Scientific Method: Step 3: HYPOTHESIS

Step 1: QUESTION
Step 2: RESEARCH
Step 3: HYPOTHESIS
Step 4: EXPERIMENT
Step 5: DATA
Step 6: CONCLUSION

Step 3: State your hypothesis

Now it's time to state your hypothesis . The hypothesis is an educated guess as to what will happen during your experiment.

The hypothesis is often written using the words "IF" and "THEN." For example, " If I do not study, then I will fail the test." The "if' and "then" statements reflect your independent and dependent variables .

The hypothesis should relate back to your original question and must be testable .

A word about variables...

Your experiment will include variables to measure and to explain any cause and effect. Below you will find some useful links describing the different types of variables.

"What are independent and dependent variables" NCES
[VIDEO] Biology: Independent vs. Dependent Variables (Nucleus Medical Media) Video explaining independent and dependent variables, with examples.

Resource Links

What is and How to Write a Good Hypothesis in Research? (Elsevier)
Hypothesis brochure from Penn State/Berks

<< Previous: Step 2: RESEARCH
Next: Step 4: EXPERIMENT >>
Last Updated: Jan 26, 2024 10:39 AM
URL: https://harford.libguides.com/scientific_method

Choose Your Test

Sat / act prep online guides and tips, what is a hypothesis and how do i write one.

General Education

Think about something strange and unexplainable in your life. Maybe you get a headache right before it rains, or maybe you think your favorite sports team wins when you wear a certain color. If you wanted to see whether these are just coincidences or scientific fact, you would form a hypothesis, then create an experiment to see whether that hypothesis is true or not.

But what is a hypothesis, anyway? If you’re not sure about what a hypothesis is--or how to test for one!--you’re in the right place. This article will teach you everything you need to know about hypotheses, including:

Defining the term “hypothesis”
Providing hypothesis examples
Giving you tips for how to write your own hypothesis

So let’s get started!

What Is a Hypothesis?

Merriam Webster defines a hypothesis as “an assumption or concession made for the sake of argument.” In other words, a hypothesis is an educated guess . Scientists make a reasonable assumption--or a hypothesis--then design an experiment to test whether it’s true or not. Keep in mind that in science, a hypothesis should be testable. You have to be able to design an experiment that tests your hypothesis in order for it to be valid.

As you could assume from that statement, it’s easy to make a bad hypothesis. But when you’re holding an experiment, it’s even more important that your guesses be good...after all, you’re spending time (and maybe money!) to figure out more about your observation. That’s why we refer to a hypothesis as an educated guess--good hypotheses are based on existing data and research to make them as sound as possible.

Hypotheses are one part of what’s called the scientific method . Every (good) experiment or study is based in the scientific method. The scientific method gives order and structure to experiments and ensures that interference from scientists or outside influences does not skew the results. It’s important that you understand the concepts of the scientific method before holding your own experiment. Though it may vary among scientists, the scientific method is generally made up of six steps (in order):

Observation
Asking questions
Forming a hypothesis
Analyze the data
Communicate your results

You’ll notice that the hypothesis comes pretty early on when conducting an experiment. That’s because experiments work best when they’re trying to answer one specific question. And you can’t conduct an experiment until you know what you’re trying to prove!

Independent and Dependent Variables

After doing your research, you’re ready for another important step in forming your hypothesis: identifying variables. Variables are basically any factor that could influence the outcome of your experiment . Variables have to be measurable and related to the topic being studied.

There are two types of variables: independent variables and dependent variables. I ndependent variables remain constant . For example, age is an independent variable; it will stay the same, and researchers can look at different ages to see if it has an effect on the dependent variable.

Speaking of dependent variables... dependent variables are subject to the influence of the independent variable , meaning that they are not constant. Let’s say you want to test whether a person’s age affects how much sleep they need. In that case, the independent variable is age (like we mentioned above), and the dependent variable is how much sleep a person gets.

Variables will be crucial in writing your hypothesis. You need to be able to identify which variable is which, as both the independent and dependent variables will be written into your hypothesis. For instance, in a study about exercise, the independent variable might be the speed at which the respondents walk for thirty minutes, and the dependent variable would be their heart rate. In your study and in your hypothesis, you’re trying to understand the relationship between the two variables.

Elements of a Good Hypothesis

The best hypotheses start by asking the right questions . For instance, if you’ve observed that the grass is greener when it rains twice a week, you could ask what kind of grass it is, what elevation it’s at, and if the grass across the street responds to rain in the same way. Any of these questions could become the backbone of experiments to test why the grass gets greener when it rains fairly frequently.

As you’re asking more questions about your first observation, make sure you’re also making more observations . If it doesn’t rain for two weeks and the grass still looks green, that’s an important observation that could influence your hypothesis. You'll continue observing all throughout your experiment, but until the hypothesis is finalized, every observation should be noted.

Finally, you should consult secondary research before writing your hypothesis . Secondary research is comprised of results found and published by other people. You can usually find this information online or at your library. Additionally, m ake sure the research you find is credible and related to your topic. If you’re studying the correlation between rain and grass growth, it would help you to research rain patterns over the past twenty years for your county, published by a local agricultural association. You should also research the types of grass common in your area, the type of grass in your lawn, and whether anyone else has conducted experiments about your hypothesis. Also be sure you’re checking the quality of your research . Research done by a middle school student about what minerals can be found in rainwater would be less useful than an article published by a local university.

Writing Your Hypothesis

Once you’ve considered all of the factors above, you’re ready to start writing your hypothesis. Hypotheses usually take a certain form when they’re written out in a research report.

When you boil down your hypothesis statement, you are writing down your best guess and not the question at hand . This means that your statement should be written as if it is fact already, even though you are simply testing it.

The reason for this is that, after you have completed your study, you'll either accept or reject your if-then or your null hypothesis. All hypothesis testing examples should be measurable and able to be confirmed or denied. You cannot confirm a question, only a statement!

In fact, you come up with hypothesis examples all the time! For instance, when you guess on the outcome of a basketball game, you don’t say, “Will the Miami Heat beat the Boston Celtics?” but instead, “I think the Miami Heat will beat the Boston Celtics.” You state it as if it is already true, even if it turns out you’re wrong. You do the same thing when writing your hypothesis.

Additionally, keep in mind that hypotheses can range from very specific to very broad. These hypotheses can be specific, but if your hypothesis testing examples involve a broad range of causes and effects, your hypothesis can also be broad.

The Two Types of Hypotheses

Now that you understand what goes into a hypothesis, it’s time to look more closely at the two most common types of hypothesis: the if-then hypothesis and the null hypothesis.

#1: If-Then Hypotheses

First of all, if-then hypotheses typically follow this formula:

If ____ happens, then ____ will happen.

The goal of this type of hypothesis is to test the causal relationship between the independent and dependent variable. It’s fairly simple, and each hypothesis can vary in how detailed it can be. We create if-then hypotheses all the time with our daily predictions. Here are some examples of hypotheses that use an if-then structure from daily life:

If I get enough sleep, I’ll be able to get more work done tomorrow.
If the bus is on time, I can make it to my friend’s birthday party.
If I study every night this week, I’ll get a better grade on my exam.

In each of these situations, you’re making a guess on how an independent variable (sleep, time, or studying) will affect a dependent variable (the amount of work you can do, making it to a party on time, or getting better grades).

You may still be asking, “What is an example of a hypothesis used in scientific research?” Take one of the hypothesis examples from a real-world study on whether using technology before bed affects children’s sleep patterns. The hypothesis read s:

“We hypothesized that increased hours of tablet- and phone-based screen time at bedtime would be inversely correlated with sleep quality and child attention.”

It might not look like it, but this is an if-then statement. The researchers basically said, “If children have more screen usage at bedtime, then their quality of sleep and attention will be worse.” The sleep quality and attention are the dependent variables and the screen usage is the independent variable. (Usually, the independent variable comes after the “if” and the dependent variable comes after the “then,” as it is the independent variable that affects the dependent variable.) This is an excellent example of how flexible hypothesis statements can be, as long as the general idea of “if-then” and the independent and dependent variables are present.

#2: Null Hypotheses

Your if-then hypothesis is not the only one needed to complete a successful experiment, however. You also need a null hypothesis to test it against. In its most basic form, the null hypothesis is the opposite of your if-then hypothesis . When you write your null hypothesis, you are writing a hypothesis that suggests that your guess is not true, and that the independent and dependent variables have no relationship .

One null hypothesis for the cell phone and sleep study from the last section might say:

“If children have more screen usage at bedtime, their quality of sleep and attention will not be worse.”

In this case, this is a null hypothesis because it’s asking the opposite of the original thesis!

Conversely, if your if-then hypothesis suggests that your two variables have no relationship, then your null hypothesis would suggest that there is one. So, pretend that there is a study that is asking the question, “Does the amount of followers on Instagram influence how long people spend on the app?” The independent variable is the amount of followers, and the dependent variable is the time spent. But if you, as the researcher, don’t think there is a relationship between the number of followers and time spent, you might write an if-then hypothesis that reads:

“If people have many followers on Instagram, they will not spend more time on the app than people who have less.”

In this case, the if-then suggests there isn’t a relationship between the variables. In that case, one of the null hypothesis examples might say:

“If people have many followers on Instagram, they will spend more time on the app than people who have less.”

You then test both the if-then and the null hypothesis to gauge if there is a relationship between the variables, and if so, how much of a relationship.

4 Tips to Write the Best Hypothesis

If you’re going to take the time to hold an experiment, whether in school or by yourself, you’re also going to want to take the time to make sure your hypothesis is a good one. The best hypotheses have four major elements in common: plausibility, defined concepts, observability, and general explanation.

#1: Plausibility

At first glance, this quality of a hypothesis might seem obvious. When your hypothesis is plausible, that means it’s possible given what we know about science and general common sense. However, improbable hypotheses are more common than you might think.

Imagine you’re studying weight gain and television watching habits. If you hypothesize that people who watch more than twenty hours of television a week will gain two hundred pounds or more over the course of a year, this might be improbable (though it’s potentially possible). Consequently, c ommon sense can tell us the results of the study before the study even begins.

Improbable hypotheses generally go against science, as well. Take this hypothesis example:

“If a person smokes one cigarette a day, then they will have lungs just as healthy as the average person’s.”

This hypothesis is obviously untrue, as studies have shown again and again that cigarettes negatively affect lung health. You must be careful that your hypotheses do not reflect your own personal opinion more than they do scientifically-supported findings. This plausibility points to the necessity of research before the hypothesis is written to make sure that your hypothesis has not already been disproven.

#2: Defined Concepts

The more advanced you are in your studies, the more likely that the terms you’re using in your hypothesis are specific to a limited set of knowledge. One of the hypothesis testing examples might include the readability of printed text in newspapers, where you might use words like “kerning” and “x-height.” Unless your readers have a background in graphic design, it’s likely that they won’t know what you mean by these terms. Thus, it’s important to either write what they mean in the hypothesis itself or in the report before the hypothesis.

Here’s what we mean. Which of the following sentences makes more sense to the common person?

If the kerning is greater than average, more words will be read per minute.

If the space between letters is greater than average, more words will be read per minute.

For people reading your report that are not experts in typography, simply adding a few more words will be helpful in clarifying exactly what the experiment is all about. It’s always a good idea to make your research and findings as accessible as possible.

Good hypotheses ensure that you can observe the results.

#3: Observability

In order to measure the truth or falsity of your hypothesis, you must be able to see your variables and the way they interact. For instance, if your hypothesis is that the flight patterns of satellites affect the strength of certain television signals, yet you don’t have a telescope to view the satellites or a television to monitor the signal strength, you cannot properly observe your hypothesis and thus cannot continue your study.

Some variables may seem easy to observe, but if you do not have a system of measurement in place, you cannot observe your hypothesis properly. Here’s an example: if you’re experimenting on the effect of healthy food on overall happiness, but you don’t have a way to monitor and measure what “overall happiness” means, your results will not reflect the truth. Monitoring how often someone smiles for a whole day is not reasonably observable, but having the participants state how happy they feel on a scale of one to ten is more observable.

In writing your hypothesis, always keep in mind how you'll execute the experiment.

#4: Generalizability

Perhaps you’d like to study what color your best friend wears the most often by observing and documenting the colors she wears each day of the week. This might be fun information for her and you to know, but beyond you two, there aren’t many people who could benefit from this experiment. When you start an experiment, you should note how generalizable your findings may be if they are confirmed. Generalizability is basically how common a particular phenomenon is to other people’s everyday life.

Let’s say you’re asking a question about the health benefits of eating an apple for one day only, you need to realize that the experiment may be too specific to be helpful. It does not help to explain a phenomenon that many people experience. If you find yourself with too specific of a hypothesis, go back to asking the big question: what is it that you want to know, and what do you think will happen between your two variables?

Hypothesis Testing Examples

We know it can be hard to write a good hypothesis unless you’ve seen some good hypothesis examples. We’ve included four hypothesis examples based on some made-up experiments. Use these as templates or launch pads for coming up with your own hypotheses.

Experiment #1: Students Studying Outside (Writing a Hypothesis)

You are a student at PrepScholar University. When you walk around campus, you notice that, when the temperature is above 60 degrees, more students study in the quad. You want to know when your fellow students are more likely to study outside. With this information, how do you make the best hypothesis possible?

You must remember to make additional observations and do secondary research before writing your hypothesis. In doing so, you notice that no one studies outside when it’s 75 degrees and raining, so this should be included in your experiment. Also, studies done on the topic beforehand suggested that students are more likely to study in temperatures less than 85 degrees. With this in mind, you feel confident that you can identify your variables and write your hypotheses:

If-then: “If the temperature in Fahrenheit is less than 60 degrees, significantly fewer students will study outside.”

Null: “If the temperature in Fahrenheit is less than 60 degrees, the same number of students will study outside as when it is more than 60 degrees.”

These hypotheses are plausible, as the temperatures are reasonably within the bounds of what is possible. The number of people in the quad is also easily observable. It is also not a phenomenon specific to only one person or at one time, but instead can explain a phenomenon for a broader group of people.

To complete this experiment, you pick the month of October to observe the quad. Every day (except on the days where it’s raining)from 3 to 4 PM, when most classes have released for the day, you observe how many people are on the quad. You measure how many people come and how many leave. You also write down the temperature on the hour.

After writing down all of your observations and putting them on a graph, you find that the most students study on the quad when it is 70 degrees outside, and that the number of students drops a lot once the temperature reaches 60 degrees or below. In this case, your research report would state that you accept or “failed to reject” your first hypothesis with your findings.

Experiment #2: The Cupcake Store (Forming a Simple Experiment)

Let’s say that you work at a bakery. You specialize in cupcakes, and you make only two colors of frosting: yellow and purple. You want to know what kind of customers are more likely to buy what kind of cupcake, so you set up an experiment. Your independent variable is the customer’s gender, and the dependent variable is the color of the frosting. What is an example of a hypothesis that might answer the question of this study?

Here’s what your hypotheses might look like:

If-then: “If customers’ gender is female, then they will buy more yellow cupcakes than purple cupcakes.”

Null: “If customers’ gender is female, then they will be just as likely to buy purple cupcakes as yellow cupcakes.”

This is a pretty simple experiment! It passes the test of plausibility (there could easily be a difference), defined concepts (there’s nothing complicated about cupcakes!), observability (both color and gender can be easily observed), and general explanation ( this would potentially help you make better business decisions ).

Experiment #3: Backyard Bird Feeders (Integrating Multiple Variables and Rejecting the If-Then Hypothesis)

While watching your backyard bird feeder, you realized that different birds come on the days when you change the types of seeds. You decide that you want to see more cardinals in your backyard, so you decide to see what type of food they like the best and set up an experiment.

However, one morning, you notice that, while some cardinals are present, blue jays are eating out of your backyard feeder filled with millet. You decide that, of all of the other birds, you would like to see the blue jays the least. This means you'll have more than one variable in your hypothesis. Your new hypotheses might look like this:

If-then: “If sunflower seeds are placed in the bird feeders, then more cardinals will come than blue jays. If millet is placed in the bird feeders, then more blue jays will come than cardinals.”

Null: “If either sunflower seeds or millet are placed in the bird, equal numbers of cardinals and blue jays will come.”

Through simple observation, you actually find that cardinals come as often as blue jays when sunflower seeds or millet is in the bird feeder. In this case, you would reject your “if-then” hypothesis and “fail to reject” your null hypothesis . You cannot accept your first hypothesis, because it’s clearly not true. Instead you found that there was actually no relation between your different variables. Consequently, you would need to run more experiments with different variables to see if the new variables impact the results.

Experiment #4: In-Class Survey (Including an Alternative Hypothesis)

You’re about to give a speech in one of your classes about the importance of paying attention. You want to take this opportunity to test a hypothesis you’ve had for a while:

If-then: If students sit in the first two rows of the classroom, then they will listen better than students who do not.

Null: If students sit in the first two rows of the classroom, then they will not listen better or worse than students who do not.

You give your speech and then ask your teacher if you can hand out a short survey to the class. On the survey, you’ve included questions about some of the topics you talked about. When you get back the results, you’re surprised to see that not only do the students in the first two rows not pay better attention, but they also scored worse than students in other parts of the classroom! Here, both your if-then and your null hypotheses are not representative of your findings. What do you do?

This is when you reject both your if-then and null hypotheses and instead create an alternative hypothesis . This type of hypothesis is used in the rare circumstance that neither of your hypotheses is able to capture your findings . Now you can use what you’ve learned to draft new hypotheses and test again!

Key Takeaways: Hypothesis Writing

The more comfortable you become with writing hypotheses, the better they will become. The structure of hypotheses is flexible and may need to be changed depending on what topic you are studying. The most important thing to remember is the purpose of your hypothesis and the difference between the if-then and the null . From there, in forming your hypothesis, you should constantly be asking questions, making observations, doing secondary research, and considering your variables. After you have written your hypothesis, be sure to edit it so that it is plausible, clearly defined, observable, and helpful in explaining a general phenomenon.

Writing a hypothesis is something that everyone, from elementary school children competing in a science fair to professional scientists in a lab, needs to know how to do. Hypotheses are vital in experiments and in properly executing the scientific method . When done correctly, hypotheses will set up your studies for success and help you to understand the world a little better, one experiment at a time.

What’s Next?

If you’re studying for the science portion of the ACT, there’s definitely a lot you need to know. We’ve got the tools to help, though! Start by checking out our ultimate study guide for the ACT Science subject test. Once you read through that, be sure to download our recommended ACT Science practice tests , since they’re one of the most foolproof ways to improve your score. (And don’t forget to check out our expert guide book , too.)

If you love science and want to major in a scientific field, you should start preparing in high school . Here are the science classes you should take to set yourself up for success.

If you’re trying to think of science experiments you can do for class (or for a science fair!), here’s a list of 37 awesome science experiments you can do at home

Ashley Sufflé Robinson has a Ph.D. in 19th Century English Literature. As a content writer for PrepScholar, Ashley is passionate about giving college-bound students the in-depth information they need to get into the school of their dreams.

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Understanding What is an Educated Guess in Science

Table of Contents

An educated guess in science, commonly referred to as a hypothesis, is a prediction or statement that can be tested through experiments and observations. It is based on careful observations, thorough research, and existing knowledge about the subject. By formulating hypotheses, scientists aim to explore and understand the natural world around us.

The scientific method is a problem-solving procedure utilized by scientists to draw conclusions and uncover new insights. It involves several steps, including identifying the problem, gathering relevant information, formulating hypotheses, testing them through experiments, analyzing results, and drawing conclusions based on the evidence gathered.

Variables play a crucial role in scientific experiments. These are factors that can change and have an impact on the outcome. The independent variable is controlled and deliberately changed by the researcher, while the dependent variable changes based on the manipulation of the independent variable. Additionally, a control is used as a standard for comparison to ensure accurate results.

In the realm of scientific inquiry, there is a distinction between scientific theory and scientific law. A scientific theory is an explanation that is supported by results obtained from tests or experiments. On the other hand, a scientific law describes the behavior of a natural phenomenon or a set of phenomena. Both theories and laws contribute to our understanding of the natural world.

When conducting scientific research, it is crucial to consider ethics and be aware of potential biases that can influence the outcomes of experiments and observations. Adhering to ethical guidelines ensures the integrity and credibility of scientific investigations, and recognizing and minimizing biases helps maintain objectivity in the pursuit of knowledge.

The steps of the scientific method guide scientists in their quest for understanding. It begins with careful observation of the natural world, followed by the formulation of a hypothesis, making predictions based on the hypothesis, conducting controlled experiments, and finally drawing conclusions based on the results obtained.

An educated guess, or a hypothesis, is a fundamental building block of scientific inquiry. It guides the direction of research and experimentation, providing a framework for investigation and discovery. By formulating hypotheses, scientists can make informed predictions and explore the intricacies of the natural world.

Key Takeaways:

An educated guess, known as a hypothesis, is a testable prediction or statement in scientific research.
The scientific method is a problem-solving procedure that involves steps like identifying a problem, formulating hypotheses, conducting experiments, and drawing conclusions.
Variables in experiments can change and impact the outcome, with the independent variable being deliberately altered by the researcher.
Scientific theory and scientific law are different concepts, with theories explaining phenomena and laws describing behavior.
Ethics and minimizing bias are crucial aspects of scientific research.

The Scientific Method and Hypothesis

The scientific method is a problem-solving procedure employed by scientists to draw conclusions, which involves identifying a problem, gathering information, making hypotheses, testing them, analyzing results, and drawing conclusions. It is a rigorous approach that ensures the credibility and reliability of scientific investigations.

At the heart of the scientific method lies the hypothesis, an essential component of scientific inquiry. An educated guess, the hypothesis is a prediction or statement that can be tested. It is formulated based on observations, research, and existing knowledge about the subject under investigation. The hypothesis serves as a guide to design experiments and gather relevant data to support or refute it.

Scientific inference and logical deduction play crucial roles in generating hypotheses. Scientists use the available evidence and reasoning to make logical deductions and form educated guesses about how phenomena work. These hypotheses are then tested through rigorous experimentation and analysis, providing valuable insights into the workings of the natural world.

By following the steps of the scientific method, scientists gain valuable knowledge and understanding of the natural world. The systematic approach allows researchers to gather evidence, form hypotheses, and test them in a controlled environment. Through rigorous experimentation and analysis, scientists draw conclusions that contribute to the advancement of scientific knowledge.

To learn more about the scientific method and its role in hypothesis formation, visit Exquisitive Education , where you can explore a range of educational resources on scientific inquiry and critical thinking.

Variables and Control in Experiments

Variables are factors that can be manipulated and measured in scientific experiments, with the independent variable intentionally changed by the researcher and the dependent variable responding to the changes. In a well-designed experiment, the independent variable is the factor that is deliberately manipulated or changed to observe its effects on the dependent variable, which is the factor that changes as a result of the manipulation.

In order to ensure the validity and reliability of the experiment, it is important to have a control group. A control group is a standard against which the experimental results can be compared. It is identical to the experimental group in every aspect, except that the independent variable is not manipulated. By comparing the results of the experimental group to the control group, scientists can determine the specific effects of the independent variable.

Types of Variables in Experiments:

There are three main types of variables in scientific experiments: independent variables, dependent variables, and controlled variables. The independent variable is the variable that is deliberately changed or manipulated by the researcher. It is the cause or input that is being tested. The dependent variable, on the other hand, is the variable that responds to the changes in the independent variable. It is the effect or outcome that is being measured or observed. Lastly, controlled variables are the factors that remain constant throughout the experiment to ensure that they do not influence the results. These variables are kept the same for both the experimental and control groups.

Understanding and controlling variables in experiments is crucial for conducting reliable and valid scientific research. By carefully manipulating and measuring variables, scientists can investigate cause-and-effect relationships and draw meaningful conclusions about the natural world.

The Role of Scientific Theory and Law

In the realm of science, a scientific theory is an explanation that is supported by consistent results obtained through experimentation or observation, whereas a scientific law describes the observed behavior of a natural phenomenon. Scientists use theories and laws to understand and explain the workings of the natural world.

A scientific theory is a comprehensive explanation that has been extensively tested and has withstood the scrutiny of repeated experiments. It provides a framework for understanding complex phenomena and allows scientists to make predictions and further investigate the subject. Theories are built upon existing knowledge and are constantly refined as new evidence emerges.

On the other hand, scientific laws are concise statements that describe a fundamental principle or relationship in nature. Laws are derived from empirical observations and are universally applicable within a specific set of conditions. Unlike theories, laws do not attempt to explain the underlying mechanisms or reasons behind a natural phenomenon, but rather serve as concise descriptions of what happens.

The Difference Between Theories and Laws

To better understand the distinction between scientific theories and laws, consider the example of gravity. Isaac Newton’s law of universal gravitation describes the force of attraction between two objects due to their mass and distance. It provides a mathematical formula to calculate the force but does not explain why gravity exists or how it works.

Albert Einstein’s theory of general relativity, on the other hand, provides a deeper understanding of gravity by describing it as the curvature of spacetime caused by the presence of mass and energy. It explains the observed phenomena such as the curvature of light around massive objects and the expansion of the universe.

In summary, scientific theories and laws are both essential in the field of science. Theories provide comprehensive explanations supported by empirical evidence, while laws describe fundamental principles or relationships in nature. Together, they form the foundation of scientific knowledge and guide further exploration and understanding of the natural world.

Ethics and Bias in Scientific Research

Ethical considerations are paramount in scientific research to ensure the welfare of subjects and the integrity of the scientific process, while bias can introduce unintended influences and affect the objectivity of results. In order to conduct ethical research, scientists must adhere to strict guidelines and principles that prioritize the safety and well-being of participants. This includes obtaining informed consent, maintaining privacy and confidentiality, and minimizing any potential harm or discomfort. By upholding ethical standards, researchers can ensure that their findings are reliable and trustworthy.

Bias, on the other hand, can pose a significant challenge to the accuracy and validity of scientific research. Bias refers to the preconceived notions or preferences that researchers may have, consciously or unconsciously, which can influence the design, execution, and interpretation of their studies. Common types of bias include confirmation bias, where researchers seek evidence that supports their preconceived ideas, and selection bias, where certain groups or individuals are favored over others in the study sample. To mitigate bias, scientists employ rigorous study designs, control groups, and blind or double-blind experimental methods to minimize subjective influence and ensure objective analysis of results.

It is crucial for scientists to acknowledge and address bias in order to uphold the credibility of their research. This involves transparently reporting any potential conflicts of interest, actively seeking diverse perspectives, and conducting peer review to ensure independent scrutiny of the study. Additionally, rigorous statistical analysis can help identify any potential biases and provide a more accurate assessment of the data. By actively working to minimize bias, researchers can maintain the integrity and validity of their findings, contributing to the overall advancement of scientific knowledge.

Importance of Addressing Bias

Addressing bias in scientific research is essential for maintaining the integrity and reliability of the findings. By mitigating bias, scientists can ensure that their research is objective, transparent, and unbiased. This allows for more accurate conclusions and fosters trust among the scientific community and the general public. Additionally, identifying and addressing biases can lead to the discovery of new insights and perspectives, as researchers actively seek out diverse viewpoints and challenge their own assumptions. Ultimately, by striving to minimize bias, scientists can contribute to the collective knowledge and understanding of the natural world.

Steps of the Scientific Method

The scientific method follows a structured process that includes observation, hypothesis formation, making predictions based on the hypothesis, conducting experiments to test the predictions, and drawing conclusions based on the results. It is a systematic approach used by scientists to investigate and understand the natural world.

1. Observation: The first step is to carefully observe and gather information about a particular phenomenon or problem. This involves using our senses or using instruments to collect data.

2. Hypothesis: Based on the observations, a hypothesis is formulated. A hypothesis is an educated guess or prediction that can be tested through experiments. It is a proposed explanation for the observed phenomenon.

3. Prediction: Once a hypothesis is formulated, predictions are made. These predictions are statements that suggest specific outcomes or patterns that should be observed if the hypothesis is correct.

4. Experiment: Experiments are conducted to test the predictions made by the hypothesis. Controlled experiments are designed with specific variables in mind. The independent variable, which is deliberately changed by the researcher, is manipulated, while the dependent variable, which changes as a result, is measured and observed.

5. Conclusion: After conducting the experiment and analyzing the results, conclusions are drawn. The data collected is evaluated to determine whether the predictions made by the hypothesis are supported or refuted. If the results support the predictions, the hypothesis is considered valid. If the results do not support the predictions, the hypothesis may need to be revised or discarded.

By following these steps, scientists can systematically investigate and understand various phenomena in the natural world. The scientific method allows for rigorous testing and analysis, ensuring that scientific knowledge is based on reliable evidence and logical reasoning.

Learn more about the scientific method and its application in various scientific disciplines at Exquisitive Education .

Definition and Importance of an Educated Guess

An educated guess, also known as a hypothesis in the scientific community, plays a crucial role in scientific investigations as it provides a starting point for experimentation and serves as a guide for further exploration. A hypothesis is a prediction or statement that can be tested, formulated based on observations, research, and existing knowledge about the subject. It acts as a tentative explanation for a scientific phenomenon or problem, allowing scientists to make predictions and design experiments to gather empirical evidence.

Scientists use the scientific method, a problem-solving procedure, to systematically investigate natural phenomena. This method involves identifying a problem, gathering relevant information, formulating hypotheses, testing them through controlled experiments, analyzing the results, and drawing conclusions. The hypothesis stage is key, as it provides a framework for experimentation and helps researchers narrow down their focus.

Variables are factors that can change in an experiment. The independent variable is deliberately changed by the researcher, while the dependent variable is observed and changes as a result. By manipulating the independent variable and measuring changes in the dependent variable, scientists can establish cause-and-effect relationships. It is also essential to have a control, which serves as a standard for comparison. This control allows researchers to isolate the effects of the independent variable, ensuring that any observed changes can be attributed to the variable being tested.

Table: Examples of Variables in Scientific Experiments

In the scientific community, theories and laws play different roles in explaining natural phenomena. A scientific theory is an explanation supported by results obtained from tests or experiments. It incorporates a broad range of evidence to explain a wide range of related observations. On the other hand, a scientific law is a description of the behavior of something in nature, typically expressed in a mathematical formula. Laws are concise descriptions of observations that have been repeatedly verified through experimentation.

Ethics and bias are important considerations in scientific research. Scientists must adhere to ethical guidelines to ensure the well-being of subjects, the integrity of data, and the overall trustworthiness of their work. Bias, whether conscious or unconscious, can influence the outcomes of experiments and observations, potentially undermining the objectivity of scientific research. Therefore, scientists should strive to minimize bias and ensure that their findings are based on rigorous and unbiased analysis.

In summary, an educated guess, or hypothesis, forms the foundation of scientific investigations. It enables scientists to formulate predictions and design experiments to gather empirical evidence. By systematically following the scientific method, scientists can explore natural phenomena, establish cause-and-effect relationships, and contribute to our understanding of the world around us.

Exploring Inference and Estimation in Science

Inference and estimation are essential tools in scientific inquiry, allowing scientists to draw conclusions and approximate values based on their observations and data. These processes play a crucial role in understanding and explaining the natural world. Through inference, scientists can make logical deductions based on available evidence to formulate educated guesses or hypotheses. This enables them to develop theories that explain phenomena and guide further investigations.

Estimation, on the other hand, involves approximating values or quantities when precise measurements may be challenging or impossible to obtain. Scientists often use estimation to make predictions or projections about future outcomes based on existing data. By employing mathematical models and statistical techniques, they can extrapolate trends, interpolate missing information, and make reasoned judgments about the behavior of natural phenomena.

In scientific experiments, inference and estimation are particularly important in the analysis of results. By interpreting data through statistical methods, scientists can determine the significance of their findings and draw meaningful conclusions. These processes also help researchers identify potential sources of error or bias and refine their methodologies for future investigations. Inference and estimation contribute to the continual advancement of scientific knowledge, allowing scientists to refine their understanding of the natural world and improve predictions and projections for various scientific disciplines.

In summary, inference and estimation are vital tools that scientists use to draw conclusions, develop theories, and approximate values in scientific inquiry. Through these processes, researchers can navigate the complexities of the natural world and expand our understanding of it. From formulating educated guesses to analyzing experimental data, inference and estimation play a foundational role in advancing scientific knowledge.

Predicting and Projecting Future Outcomes

Prediction and projection are valuable aspects of scientific inquiry, as they enable scientists to anticipate and envision future outcomes based on existing knowledge and data. By analyzing patterns and trends, scientists can make informed judgments about what may occur in the future within various scientific disciplines. These predictions and projections serve as a stepping stone towards further exploration and discovery, guiding researchers towards new avenues of investigation.

When predicting future outcomes, scientists draw upon a vast array of information gathered through research, experiments, and observations. This data acts as a foundation for understanding the behavior of natural phenomena and allows scientists to establish correlations and patterns. Through careful analysis, scientists can make reasonable predictions about how these phenomena may behave in the future, providing valuable insights into the potential consequences of certain actions or events.

Projection, on the other hand, involves taking existing data and applying it to future scenarios. By extrapolating from historical trends and patterns, scientists can project how certain variables may change and impact the natural world. These projections can assist in decision-making processes and help society plan for and mitigate potential risks or challenges.

Utilizing Predictions and Projections

Predictions and projections form a vital part of scientific research and exploration. By utilizing these methods, scientists can hypothesize and test different scenarios, contributing to our understanding of the world and enabling us to make more informed choices in various fields. From climate change and environmental conservation to healthcare advancements and technological innovations, predictions and projections play a crucial role in shaping the future.

As we continue to explore the unknown and push the boundaries of scientific knowledge, predictions and projections will remain invaluable tools in guiding our understanding and shaping the world we live in. Through careful analysis, experimentation, and the utilization of existing data, scientists can uncover new insights and help shape a brighter future for all.

Preliminary Assessment and Rough Calculation

Preliminary assessments and rough calculations serve as initial steps in scientific investigations, providing scientists with a basis for further analysis and decision-making. These processes allow researchers to make informed judgments and estimations before delving into more complex experiments or analyses.

When conducting a preliminary assessment, scientists gather relevant data and information to gain a general understanding of the subject matter. This involves reviewing existing studies, conducting literature reviews, and examining previous research findings. By doing so, scientists can identify any knowledge gaps or areas that require further investigation.

Once the preliminary assessment is complete, scientists move on to rough calculations. These calculations are often used to make estimations or approximations of key variables or outcomes. They involve applying reasoned judgment, extrapolation, and interpolation to arrive at rough values or ranges. While the accuracy of these calculations may be limited, they provide a starting point for more rigorous analysis and experimentation.

Overall, preliminary assessments and rough calculations are essential tools in the scientific process. They allow scientists to develop an initial understanding of a phenomenon or problem, guiding them towards more focused research and experimentation. By utilizing these early steps effectively, researchers can lay the foundation for meaningful scientific discoveries and advancements.

Exploring the Role of Hypothesis in Science

Hypotheses, often referred to as educated guesses, are integral to scientific research, guiding the design of experiments and providing a framework for investigating specific questions or phenomena. These hypotheses are based on observations, research, and existing knowledge about the subject at hand. By formulating a hypothesis, scientists can make predictions and test their ideas in a systematic and objective manner.

One of the fundamental aspects of scientific inquiry is the use of the scientific method. This problem-solving procedure allows scientists to gather information, make hypotheses, test them through experimentation, analyze the results, and draw conclusions. The hypothesis serves as the initial prediction or statement that is tested in an experiment, helping scientists to focus their efforts and determine the direction of their research.

In scientific experiments, variables play a crucial role. Variables are factors that can change during the course of an experiment, and they can have a direct impact on the outcome. The independent variable is deliberately changed by the researcher, while the dependent variable is the one that changes as a result. Having a control, which is a standard to compare results to, ensures that any changes observed can be attributed to the independent variable and not other factors.

In addition to the role of hypotheses and variables, the distinction between scientific theory and scientific law is also significant. A scientific theory is an explanation that is supported by results obtained from tests or experiments, while a scientific law describes the behavior of something in nature. These concepts help to shape our understanding of the natural world and provide frameworks for further scientific exploration.

It’s important to note that ethics and bias can influence scientific research. Scientists are guided by ethical considerations to ensure the welfare of subjects, accurate reporting, and responsible conduct. Additionally, biases, both conscious and unconscious, can influence the outcomes of experiments and observations. Recognizing and addressing these factors is essential for maintaining the integrity of scientific research.

In conclusion, hypotheses, or educated guesses, play a vital role in scientific research. They guide the design of experiments, allow scientists to make predictions, and provide a framework for investigating specific questions or phenomena. By understanding the role of hypotheses in the scientific method and recognizing the impact of variables, theories, laws, ethics, and bias, we can gain a deeper appreciation for the process of scientific inquiry and its contributions to our understanding of the natural world.

In conclusion, understanding what an educated guess is in science, commonly known as a hypothesis, is crucial for comprehending and advancing our scientific knowledge. An educated guess, or hypothesis, is a prediction or statement that can be tested through observation, research, and existing knowledge. It serves as a starting point for scientific exploration, guiding the formulation of experiments and driving the course of scientific inquiry.

The scientific method, a problem-solving procedure employed by scientists, relies heavily on hypotheses. It involves identifying a problem, gathering information, making hypotheses, testing them through experiments, analyzing the results, and drawing conclusions. By adhering to this structured approach, scientists can validate or refine their educated guesses, ultimately contributing to the accumulation of scientific knowledge.

Variables, such as the independent and dependent variables, play a crucial role in scientific experiments. The independent variable, purposely manipulated by researchers, causes changes in the dependent variable. Additionally, having a control group enables scientists to compare results and determine the impact of the independent variable. This controlled experimentation allows for reliable conclusions to be drawn from the data.

Ethics and bias also exert influence throughout the scientific research process. Maintaining ethical standards is essential to protect the well-being of subjects and ensure the integrity of the results. Meanwhile, acknowledging and addressing bias helps to eliminate any distortions that may skew the outcomes of experiments and observations.

In summary, understanding the concept of an educated guess, or hypothesis, is fundamental in scientific inquiry. By utilizing the scientific method, considering variables, acknowledging ethical considerations, and mitigating bias, scientists can make substantial contributions to our understanding of the natural world. Continued exploration and investigation, guided by educated guesses, pave the way for new discoveries and advancements in various scientific disciplines.

Q: What is an educated guess in science?

A: An educated guess in science, also known as a hypothesis, is a prediction or statement that can be tested. It is based on observations, research, and existing knowledge about the subject.

Q: What is the scientific method?

A: The scientific method is a problem-solving procedure used by scientists to draw conclusions. It involves identifying a problem, gathering information, making hypotheses, testing them, analyzing results, and drawing conclusions.

Q: What are variables in experiments?

A: Variables are factors that can change in an experiment. The independent variable is deliberately changed by the researcher, while the dependent variable changes as a result.

Q: What is a control in an experiment?

A: A control is a standard used to compare the results of an experiment to. It helps scientists assess the impact of the independent variable on the dependent variable.

Q: What is the difference between a scientific theory and a scientific law?

A: A scientific theory is an explanation backed by results obtained from tests or experiments. A scientific law describes the behavior of something in nature.

Q: How do ethics and bias play a role in scientific research?

A: Ethics play a role in scientific research by ensuring that experiments are conducted responsibly and with respect for human and animal subjects. Bias can influence the outcomes of experiments and observations, which is why it is crucial for scientists to strive for objectivity.

Q: What are the steps of the scientific method?

A: The steps of the scientific method are observation, hypothesis formation, making predictions, conducting experiments, and drawing conclusions.

Q: Why is an educated guess important in science?

A: An educated guess, or hypothesis, is important in science as it guides the formulation of experiments and drives scientific investigations. It allows scientists to make predictions and test their understanding of the natural world.

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Formative Assessment Probe

What Is a Hypothesis?

By Page Keeley

Uncovering Student Ideas in Science, Volume 3: Another 25 Formative Assessment Probes

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This is the new updated edition of the first book in the bestselling Uncovering Student Ideas in Science series. Like the first edition of volume 1, this book helps pinpoint what your students know (or think they know) so you can monitor their learning and adjust your teaching accordingly. Loaded with classroom-friendly features you can use immediately, the book includes 25 “probes”—brief, easily administered formative assessments designed to understand your students’ thinking about 60 core science concepts.

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The purpose of this assessment probe is to elicit students’ ideas about hypotheses. The probe is designed to find out if students understand what a hypothesis is, when it is used, and how it is developed.

Type of Probe

Justified List

Related Concepts

hypothesis, nature of science, scientific inquiry, scientific method

Explanation

The best choices are A, B, G, K, L, and M. However, other possible answers open up discussions to contrast with the provided definition. A hypothesis is a tentative explanation that can be tested and is based on observation and/or scientific knowledge such as that that has been gained from doing background research. Hypotheses are used to investigate a scientific question. Hypotheses can be tested through experimentation or further observation, but contrary to how some students are taught to use the “scientific method,” hypotheses are not proved true or correct. Students will often state their conclusions as “My hypothesis is correct because my data prove…,” thereby equating positive results with proof (McLaughlin 2006, p. 61). In essence, experimentation as well as other means of scientific investigation never prove a hypothesis—the hypothesis gains credibility from the evidence obtained from data that support it. Data either support or negate a hypothesis but never prove something to be 100% true or correct.

Hypotheses are often confused with questions. A hypothesis is not framed as a question but rather provides a tentative explanation in response to the scientific question that leads the investigation. Sometimes the word hypothesis is oversimplified by being defined as “an educated guess.” This terminology fails to convey the explanatory or predictive nature of scientific hypotheses and omits what is most important about hypotheses: their purpose. Hypotheses are developed to explain observations, such as notable patterns in nature; predict the outcome of an experiment based on observations or prior scientific knowledge; and guide the investigator in seeking and paying attention to the right data. Calling a hypothesis a “guess” undermines the explanation that underscores a hypothesis.

Predictions and hypotheses are not the same. A hypothesis, which is a tentative explanation, can lead to a prediction. Predictions forecast the outcome of an experiment but do not include an explanation. Predictions often use if-then statements, just as hypotheses do, but this does not make a prediction a hypothesis. For example, a prediction might take the form of, “If I do [X], then [Y] will happen.” The prediction describes the outcome but it does not provide an explanation of why that outcome might result or describe any relationship between variables.

Sometimes the words hypothesis , theory , and law are inaccurately portrayed in science textbooks as a hierarchy of scientific knowledge, with the hypothesis being the first step on the way to becoming a theory and then a law. These concepts do not form a sequence for the development of scientific knowledge because each represents a different type of knowledge.

Not every investigation requires a hypothesis. Some types of investigations do not lend themselves to hypothesis testing through experimentation. A good deal of science is observational and descriptive—the study of biodiversity, for example, usually involves looking at a wide variety of specimens and maybe sketching and recording their unique characteristics. A biologist studying biodiversity might wonder, “What types of birds are found on island X?” The biologist would observe sightings of birds and perhaps sketch them and record their bird calls but would not be guided by a specific hypothesis. Many of the great discoveries in science did not begin with a hypothesis in mind. For example, Charles Darwin did not begin his observations of species in the Galapagos with a hypothesis in mind.

Contrary to the way hypotheses are often stated by students as an unimaginative response to a question posed at the beginning of an experiment, particularly those of the “cookbook” type, the generation of hypotheses by scientists is actually a creative and imaginative process, combined with the logic of scientific thought. “The process of formulating and testing hypotheses is one of the core activities of scientists. To be useful, a hypothesis should suggest what evidence would support it and what evidence would refute it. A hypothesis that cannot in principle be put to the test of evidence may be interesting, but it is not likely to be scientifically useful” (AAAS 1988, p. 5).

Curricular and Instructional Considerations

Elementary Students

In the elementary school grades, students typically engage in inquiry to begin to construct an understanding of the natural world. Their inquiries are initiated by a question. If students have a great deal of knowledge or have made prior observations, they might propose a hypothesis; in most cases, however, their knowledge and observations are too incomplete for them to hypothesize. If elementary school students are required to develop a hypothesis, it is often just a guess, which does little to contribute to an understanding of the purpose of a hypothesis. At this grade level, it is usually sufficient for students to focus on their questions, instead of hypotheses (Pine 1999).

Middle School Students

At the middle school level, students develop an understanding of what a hypothesis is and when one is used. The notion of a testable hypothesis through experimentation that involves variables is introduced and practiced at this grade level. However, there is a danger that students will think every investigation must include a hypothesis. Hypothesizing as a skill is important to develop at this grade level but it is also important to develop the understandings of what a hypothesis is and why and how it is developed.

High School Students

At this level, students have acquired more scientific knowledge and experiences and so are able to propose tentative explanations. They can formulate a testable hypothesis and demonstrate the logical connections between the scientific concepts guiding a hypothesis and the design of an experiment (NRC 1996).

Administering the Probe

This probe is best used as is at the middle school and high school levels, particularly if students have been previously exposed to the word hypothesis or its use. Remove any answer choices students might not be familiar with. For example, if they have not encountered if-then reasoning, eliminate this distracter. The probe can also be modified as a simpler version for students in grades 3–5 by leaving out some of the choices and simplifying the descriptions.

K–4 Understandings About Scientific Inquiry

Scientific investigations involve asking and answering a question and comparing the answer with what scientists already know about the world.
Scientists develop explanations using observations (evidence) and what they already know about the world (scientific knowledge).

5–8 Understandings About Scientific Inquiry

Different kinds of questions suggest different kinds of investigations. Some investigations involve observing and describing objects, organisms, or events; some involve collecting specimens; some involve experiments; some involve seeking more information; some involve discovery of new objects and phenomena; and some involve making models.
Current scientific knowledge and understanding guide scientific investigations. Different scientific domains employ different methods, core theories, and standards to advance scientific knowledge and understanding.

5–8 Science as a Human Endeavor

Science is very much a human endeavor, and the work of science relies on basic human qualities such as reasoning, insight, energy, skill, and creativity.

9–12 Abilities Necessary to Do Scientific Inquiry

Identify questions and concepts that guide scientific investigations.*

9–12 Understandings About Scientific Inquiry

Scientists usually inquire about how physical, living, or designed systems function. Conceptual principles and knowledge guide scientific inquiries. Historical and current scientific knowledge influence the design and interpretation of investigations and the evaluation of proposed explanations made by other scientists.

*Indicates a strong match between the ideas elicited by the probe and a national standard’s learning goal.

K–2 Scientific Inquiry

People can often learn about things around them by just observing those things carefully, but sometimes they can learn more by doing something to the things and noting what happens.

3–5 Scientific Inquiry

Scientists’ explanations about what happens in the world come partly from what they observe and partly from what they think. Sometimes scientists have different explanations for the same set of observations. That usually leads to their making more observations to resolve the differences.

6–8 Scientific Inquiry

Scientists differ greatly in what phenomena they study and how they go about their work. Although there is no fixed set of steps that all scientists follow, scientific investigations usually involve the collection of relevant evidence, the use of logical reasoning, and the application of imagination in devising hypotheses and explanations to make sense of the collected evidence.*

6–8 Values and Attitudes

Even if they turn out not to be true, hypotheses are valuable if they lead to fruitful investigations.*

9–12 Scientific Inquiry

Hypotheses are widely used in science for choosing what data to pay attention to and what additional data to seek and for guiding the interpretation of the data (both new and previously available).*

Related Research

Students generally have difficulty with explaining how science is conducted because they have had little contact with real scientists. Their familiarity with doing science, even at older ages, is “school science,” which is often not how science is generally conducted in the scientific community (Driver et al. 1996).
Despite over 10 years of reform efforts in science education, research still shows that students typically have inadequate conceptions of what science is and what scientists do (Schwartz 2007).
Upper elementary school and middle school students may not understand experimentation as a method of testing ideas, but rather as a method of trying things out or producing a desired outcome (AAAS 1993).
Middle school students tend to invoke personal experiences as evidence to justify their hypothesis. They seem to think of evidence as selected from what is already known or from personal experience or secondhand sources, not as information produced through experiment (AAAS 1993).

Related NSTA Resources

American Association for the Advancement of Science (AAAS). 1993. Benchmarks for science literacy. New York: Oxford University Press.

Keeley, P. 2005. Science curriculum topic study: Bridging the gap between standards and practice. Thousand Oaks, CA: Corwin Press.

McLaughlin, J. 2006. A gentle reminder that a hypothesis is never proven correct, nor is a theory ever proven true. Journal of College Science Teaching 36 (1): 60–62.

National Research Council (NRC). 1996. National science education standards. Washington, DC: National Academy Press.

Schwartz, R. 2007. What’s in a word? How word choice can develop (mis)conceptions about the nature of science. Science Scope 31 (2): 42–47.

VanDorn, K., M. Mavita, L. Montes, B. Ackerson, and M. Rockley. 2004. Hypothesis-based learning. Science Scope 27: 24–25.

Suggestions for Instruction and Assessment

The “scientific method” is often the first topic students encounter when using textbooks and this can erroneously imply that there is a rigid set of steps that all scientists follow, including the development of a hypothesis. Often the scientific method described in textbooks applies to experimentation, which is only one of many ways scientists conduct their work. Embedding explicit instruction of the various ways to do science in the actual investigations students do throughout the year as well as in their studies of investigations done by scientists is a better approach to understanding how science is done than starting off the year with the scientific method in a way that is devoid of a context through which students can learn the content and process of science.
Students often participate in science fairs that may follow a textbook scientific method of posing a question, developing a hypothesis, and so on, that incorrectly results in students “proving” their hypothesis. Make sure students understand that a hypothesis can be disproven, but it is never proven, which implies 100% certainty.
Help students understand that science begins with a question. The structure of some school lab reports may lead students to believe that all investigations begin with a hypothesis. While some investigations do begin with a hypothesis, in most cases, they begin with a question. Sometimes it is just a general question.
A technique to help students maintain a consistent image of science as inquiry throughout the year by paying more careful attention to the words they use is to create a “caution words” poster or bulletin board (Schwartz 2007). Important words that have specific meanings in science but are often used inappropriately in the science classroom and through everyday language can be posted in the room as a reminder to pay careful attention to how students are using these words. For example, words like hypothesis and scientific method can be posted here. Words that are banned when referring to hypotheses include prove, correct, and true.
Use caution when asking students to write lab reports that use the same format regardless of the type of investigation conducted. The format used in writing about an investigation may imply a rigid, fixed process or erroneously misrepresent aspects of science, such as that hypotheses are developed for every scientific investigation.
Avoid using hypotheses with younger children when they result in guesses. It is better to start with a question and have students make a prediction about what they think will happen and why. As they acquire more conceptual understanding and experience a variety of observations, they will be better prepared to develop hypotheses that reflect the way science is done.
Avoid using “educated guess” as a description for hypothesis. The common meaning of the word guess implies no prior knowledge, experience, or observations.
Scaffold hypothesis writing for students by initially having them use words like may in their statements and then formalizing them with if-then statements. For example, students may start with the statement, “The growth of algae may be affected by temperature.” The next step would be to extend this statement to include a testable relationship, such as, “If the temperature of the water increases, then the algae population will increase.” Encourage students to propose a tentative explanation and then consider how they would go about testing the statement.

American Association for the Advancement of Science (AAAS). 1988. Science for all Americans. New York: Oxford University Press.

Driver, R., J. Leach, R. Millar, and P. Scott. 1996. Young people’s images of science. Buckingham, UK: Open University Press.

Pine, J. 1999. To hypothesize or not to hypothesize. In Foundations: A monograph for professionals in science, mathematics, and technology education. Vol. 2. Inquiry: Thoughts, views, and strategies for the K–5 classroom. Arlington, VA: National Science Foundation.

1.6: Hypothesis, Theories, and Laws

Learning Objectives

What is a Fact?

What is a Hypothesis?

What is a Theory?

What is a Law?

What is a Belief?

Laws vs. Theories

Video \(\PageIndex{1}\): What’s the difference between a scientific law and theory?

Contributions & Attributions

What is a scientific hypothesis?

Hypothesis basics

Additional resources

Types of scientific hypotheses

Scientific theory vs. scientific hypothesis

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1.2 The Scientific Methods

Teacher Support

Section Key Terms

Scientific Methods

Using Models and the Scientific Processes

Scientific Laws and Theories

Check Your Understanding

Biology library

Introduction

Scientific method example: Failure to toast

2. Ask a question.

3. Propose a hypothesis.

4. Make predictions.

5. Test the predictions.

Logical possibility

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Scientific Method: Step 3: HYPOTHESIS

Step 3: State your hypothesis

Resource Links

Choose Your Test

What Is a Hypothesis?

Independent and Dependent Variables

Elements of a Good Hypothesis

Writing Your Hypothesis

The Two Types of Hypotheses

#1: If-Then Hypotheses

#2: Null Hypotheses

4 Tips to Write the Best Hypothesis

#1: Plausibility

#2: Defined Concepts

#3: Observability

#4: Generalizability

Hypothesis Testing Examples

Experiment #1: Students Studying Outside (Writing a Hypothesis)

Experiment #2: The Cupcake Store (Forming a Simple Experiment)

Experiment #3: Backyard Bird Feeders (Integrating Multiple Variables and Rejecting the If-Then Hypothesis)

Experiment #4: In-Class Survey (Including an Alternative Hypothesis)

Key Takeaways: Hypothesis Writing

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Understanding What is an Educated Guess in Science

The Scientific Method and Hypothesis

Variables and Control in Experiments

Types of Variables in Experiments:

The Role of Scientific Theory and Law

The Difference Between Theories and Laws

Ethics and Bias in Scientific Research

Importance of Addressing Bias

Steps of the Scientific Method

Definition and Importance of an Educated Guess

Table: Examples of Variables in Scientific Experiments

Exploring Inference and Estimation in Science

Predicting and Projecting Future Outcomes

Utilizing Predictions and Projections

Preliminary Assessment and Rough Calculation

Exploring the Role of Hypothesis in Science