Scientific theory

A scientific theory is an explanation of something in the natural world. It has been tested many times and has evidence that supports it. This testing uses the scientific method. Theories are checked through watching, measuring, and looking at results, often in special tests called experiments. When we can't do experiments, theories are still checked using abductive reasoning. Strong theories have been tested a lot and still explain what we see.

A scientific theory is different from a scientific fact. A fact is something we see, like leaves falling from a tree. A theory connects many facts and explains why they happen. For example, gravity explains why leaves fall. Theories can also tell us about things we haven't seen yet. Stephen Jay Gould said facts and theories are different, not one better than the other. Facts are the information, and theories help us understand that information.

In everyday talk, people might use "theory" to mean a wild guess. But in science, a theory is an idea that has been tested a lot and is trusted. The best theories explain many different things in a simple way. Sometimes, as we learn more, a theory might need to change or even be replaced by a better one. But some theories, like evolution or the heliocentric theory, are so strong they are unlikely to change.

Scientific theories help us understand the universe. They explain things like electricity, chemistry, and the stars. Theories let scientists make predictions and help create new technology and medicine. While scientists can never fully prove a theory, they can show that the evidence supports it. This helps us learn more about the world around us.

Types

Albert Einstein talked about two kinds of scientific theories. One kind is called "constructive theories." These help us understand how things happen. The other kind is called "principle theories." These are general ideas that come from watching and measuring things.

Characteristics

A scientific theory is a way to explain something in nature that has been tested many times and has strong evidence to support it. Theories help us understand the world better by making predictions that can be checked through experiments and observations.

For a theory to be accepted, it must make predictions that can be tested. Good theories are supported by lots of evidence and fit with what we already know. They should also be simple and easy to test, making it easier for scientists to discover more about the world.

Formation

The scientific method is a way scientists test ideas called hypotheses. They make guesses about what will happen and then do experiments to see if those guesses are right. If the guesses match the experiments, scientists might build a bigger explanation called a theory.

When scientists do many experiments about a certain topic, they can create a theory. This theory tries to explain what they have seen. Even if a theory isn’t perfect, it can still be very helpful. Scientists keep testing theories to make sure they stay accurate. A theory that many scientists agree on is considered the best explanation we have right now.

Modification and improvement

When experiments show results that don't match a theory, scientists check if the experiment was done right. If it was, they try to improve the theory. Sometimes small changes work, and sometimes bigger ones are needed. Over time, theories get better and can predict things more accurately.

Sometimes, a whole new theory is needed if the old one can't explain the new results. Even then, the old theory might still be useful for other things. For example, Newton's ideas about gravity worked well for a long time, even though they didn't explain everything.

Unification

Sometimes, scientists find that two theories are actually parts of one bigger theory. For example, we now know that electricity and magnetism are two sides of the same thing called electromagnetism.

Example: Relativity

In 1905, Albert Einstein created the theory of special relativity. He showed that the speed of light stays the same no matter how things move. This led to new ideas like time changing speed and things seeming shorter when moving fast. Later, Einstein expanded this to include gravity, creating general relativity. This shows how space and time can bend because of gravity. Even though general relativity explains more, scientists still use Newton's simpler ideas for many calculations.

Theories and laws

See also: Scientific law

Scientific laws and scientific theories both come from the scientific method. They help us understand and predict how nature behaves.

Laws describe what happens under certain conditions. Theories explain why things happen the way they do. Theories are broader and can include several laws.

It is a common idea that theories become laws when we learn more. But this isn’t true. Theories stay theories, and laws stay laws. Both can be proven wrong if new evidence shows something different. Theories help us organize and explain scientific facts, which are observations about the world. As we discover new facts, theories might change or new theories might be created to include them.

About theories

Theories as axioms

Logical positivists thought of scientific theories like statements in a special kind of language. This language included simple observations like "the sun rises in the east," definitions, and math facts. Things we can't see directly, like atoms or radio waves, were treated as ideas that help explain what we observe. In this view, theories work like starting points from which we can figure out what should happen.

Theories as models

Main article: Scientific model

Today, many scientists think of theories as models that represent how the real world works, similar to how a map shows a city. A model is a way to picture reality, even if it isn't the real thing itself. For example, a model of the Solar System might use simple objects to stand for the Sun and planets, with rules about how they move. By testing these models, scientists can see if they match what actually happens in space.

Differences between theory and model

Main article: Conceptual model

Some thinkers say that theories not only describe what happens but also explain why it happens, while models mainly describe things.

Assumptions in formulating theories

When creating theories, scientists sometimes start with ideas that haven't been proven yet. These starting points help build the theory, and later tests can show if they match reality.

Descriptions

From philosophers of science

Karl Popper explained what makes a scientific theory special in a few simple ways:

1. It’s easy to find things that seem to support any theory, but real support comes from tests that could have shown the theory wrong.
2. A good theory tells us what cannot happen. The more it rules out, the better it is.
3. A theory must be able to be tested and possibly shown wrong. This ability to be tested is what makes it scientific.
4. When we test a theory, we are trying to prove it wrong. Only when these tests fail to show it wrong do we say the theory is supported.

Stephen Hawking added that a good theory must explain many observations using just a few ideas, and it should make clear predictions about what we will see in the future.

Some thinkers argue that theories also need to be creative and bring new ideas.

Analogies and metaphors

People have used many ways to describe what a scientific theory is like. One idea is that a theory is like a detailed map that helps us understand the world.

Galileo Galilei said that the universe is like a book written in the language of mathematics, with shapes and numbers that we must learn to read.

Another thinker compared nature to a large library where each book gives us special ways to understand different parts of the world.

In physics

In physics, a theory is a set of ideas that help scientists make predictions about how things will behave in experiments. These ideas come from a few basic rules.

A good example is classical electromagnetism. It uses a few important equations called Maxwell's equations to explain how electric and magnetic forces work. These equations have been tested many times and work very well.

Within electromagnetism, scientists have ideas about how it works in different situations. Some of these ideas have been tested a lot, while others are still being studied. For example, there is an idea called the radiation reaction force. We can see its effects in big machines called synchrotrons.

Examples

Many subjects do not have one main theory, but they still have strong ideas with lots of evidence. Theories often use information from many different areas.

Some well-known theories include:

• Biology: cell theory, theory of evolution, abiogenesis, germ theory
• Chemistry: collision theory, kinetic theory of gases, molecular theory
• Physics: atomic theory, Big Bang theory, theory of relativity, quantum field theory
• Earth science: Climate change theory, plate tectonics theory
• Astronomy: Stellar evolution, solar nebular model

Explanatory notes

A scientific theory explains how nature works. It is supported by many tests and evidence using careful scientific methods. These methods include watching, measuring, and checking results.

When possible, theories are tested in controlled experiments. If experiments are not possible, theories are examined using logical thinking.