This is the simplest explanation of Schödinger’s Cat Experiment.

Do you struggle to wrap your head around the Cat Experiment?

So if you want to finally understand Schrödinger’s Cat Experiment once and for all, then you’re in the right place.

Let’s jump right in!

## Table of Contents

- Schrödinger’s Cat Experiment Made Simple
- WARNING: Don’t Attempt This Experiment
- Schrödinger’s Cat Explained: The Experiment
- Radioactive Decay Refresher
- Schrödinger’s Cat Explained: The Results
- Schrödinger’s Cat Explained: Conclusion

## Schrödinger’s Cat Experiment Made Simple

Nature Noon rarely dives into physics, let alone the bazaar world of *quantum* physics.

However, some quantum concepts are certainly worth knowing about, extraordinarily fascinating and straightforward to grasp.

Easily, among the most famous quantum experiments was *Schrödinger’s cat*.

Without further ado, let’s dive into *Schrödinger’s cat explained:*

## WARNING: Don’t Attempt This Experiment

Schrödinger’s cat experiment is what we call a *thought experiment*.

In other words, we don’t *actually* conduct the experiment. We use only our imagination and reasoning instead.

In fact, as we will later learn, it is truly impossible to physically conduct Schrödinger’s cat experiment, even if we wanted to.

That being said, please **under no circumstances attempt to conduct this experiment**.

This article is purely to educate one on the purpose of the experiment, not to perform it.

Among Schrödinger’s prolific, Nobel-Prize-winning career was his infamous cat experiment.

In fact, this benchmark experiment has been the subject of jokes, shirts, TV show episodes, and more.

However, Schrödinger’s cat experiment has been both misinterpreted and misunderstood over time.

Hence, this article’s simple approach helps us fully understand where brilliant Erwin was coming from.

## Schrödinger’s Cat Explained: The Experiment

First, a cat is placed inside a sealed box for one hour.

Also, inside the box are:

- A container of radioactive material
- A Geiger Counter (a simple machine that detects radioactive particles)
- A hammer
- A container of deadly cyanide

Using the correct radioactive material allows a precisely 50/50 chance that a single radioactive particle will be emitted within one hour.

If you are uncertain as to *why* radioactive material will do this …

## Radioactive Decay Refresher

Radioactive materials contain extra energy and feel unstable. Therefore, to become stable once again, they release or *emit some* of this energy in particles.

We call this *radioactive decay*.

Next, our Geiger Counter will wait for a radioactive particle to be emitted.

And, if it records a particle, it will let the hammer drop.

As a result, the hammer breaks open the lethal cyanide container, killing the cat.

At last, when you open the box, the cat will either be dead or alive, depending on the outcome.

However, before opening the box, the cat is both dead *and* alive.

In fact, this is the very purpose of Schrödinger’s cat experiment.

But, how could that possibly be?

## Schrödinger’s Cat Explained: The Results

Basically, nothing about the matter is certain until we observe it.

In fact, this thought process is known as the *Copenhagen Interpretation* of quantum physics.

In other words, simply looking at matter actually changes the outcome of what happens to it.

Weird, huh?

Indeed, that is why we proclaimed previously in this article that one could not physically conduct this experiment, even if they so desired.

You see, the primary focus of the experiment is that *prior to* observation, the cat is both dead and alive simultaneously.

Therefore, visually observing or monitoring the cat during its *hour-in-the-bo*x time would alter and prevent an outcome.

Trippy to think about, isn’t it?

Realistically, yes, the matter *could* be at any place. But, the **probability** of the matter being at some places is much higher than in others.

For instance, a carbon atom in your diamond ring could be on the Moon right now.

However, it’s much more likely that the carbon atom is on your finger.

You can’t know where something is unless you see it.

Until you see it, the Copenhagen Interpretation says that the atom is there and is not there.

Until you see the particle, you have no idea if it’s there or not.

This makes sense in quantum physics, but not in real-world physics.

Actually, this very style of thinking was the purpose of Schrödinger’s cat.

You see, while Schrödinger found such possibilities true for single particles, they would not be possible on larger objects, like cats.

In fact, Schrödinger created his famous cat thought experiment to show how absurd the Copenhagen Interpretation was for larger objects.

What a character.

## Schrödinger’s Cat Explained: Conclusion

Ok, we’ve just explained a lot.

But, to sum up, let’s break it down into three easy bullet points:

- After one hour in the experimental box, Schrödinger’s cat stands at a 50% chance of being dead and a 50% chance of being alive.

- But, while the cat is in the box, it is both dead
**AND**alive simultaneously (*Copenhagen Interpretation*). You don’t know what you can’t observe.

- Schrödinger’s cat experiment was hypothetically used to show Schrödinger’s disagreed with the
*Copenhagen Interpretation*for larger objects, like a cat.