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Obviously, a cat can’t be both alive and dead-vampire cats excluded-which was exactly Schrödinger’s point. The problem is that this would mean that until the very last moment before someone opens the box, the cat is somehow both alive and dead at the same time. Now, if we scale up the Copenhagen theory from the quantum level all the way up Schrödinger’s scenario, then all outcomes simultaneously exist in all possible configurations until one opens the box, which, according to the complex mathematics of quantum mechanics, forces only one outcome: the cat is either alive or dead. Thus, after an hour, there is equal probability of the cat being alive or dead, and an observer can open the box and see which state the cat is in.
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If the particle is emitted and hits the Geiger counter, a relay is set in motion whereby the hammer shatters the flask, releasing the gas and killing the cat. Over the course of an hour, there is a chance that the radioactive substance might emit a particle (specifically, an alpha particle), and an equal chance that it might not. Schrödinger found this theory flawed, and to demonstrate why, he asked his colleagues to imagine a “ridiculous case” where a cat, a tiny bit of radioactive material, a Geiger counter, a hammer, and a glass vial of poison were all locked inside a single box. The Copenhagen theory stated, essentially, we can’t know what state or place an atomic particle is in until it’s observed, and so that particle could hypothetically be in all possible states or places until then. In 1935, Schrödinger came up with a famous thought experiment, now eponymously referred to as Schrödinger’s cat, as a criticism of what’s known as the Copenhagen interpretation of quantum mechanics. Austrian physicist Erwin Schrödinger won the 1933 Nobel Prize in Physics for his work in quantum mechanics, a branch of physics that studies the nature and behavior of subatomic particles.