6.2: Amplitudes

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What makes quantum mechanics so different from the propagation of uncertainty in classical physics is that it’s not directly the probabilities that propagate, but rather these things called amplitudes. Suppose you constructed something like a SternGerlach machine, and propagated the system through it using the rules of classical physics. Suppose the path of the particle has two places where there are two possibilities. Suppose that at each of these branches, the probability of each branch is 1/2. That would leave you with four possibilities in the end. The rules of probability tell you that the chance that a particle will take a certain branch at the first choice, and a certain branch at the second choice, means that you have to multiply the probability of each branch at each choice. In this example, that would leave you with an overall 1/4 probability of the particle having gone through a given path.

In quantum mechanics, however, the situation may be entirely different. The probabilities you get at the end cannot be simply calculated from the probabilities you would get if you evaluated each choice in isolation.

There is another realm of mechanics where paths taken by the system depend more directly on amplitudes than on probabilities, and that realm is wave mechanics. If two waves pass each other, it’s possible to get destructive or constructive interference, possibly giving you wave intensities that are the sum of the two individual intensities, but also possibly giving you wave intensities of zero. Indeed, it is from the amplitudes of waves that quantum mechanics gets the term amplitudes for the thing that it propagates in order ultimately to calculate probabilities. Quantum mechanics bears a lot of similarities to more general wave mechanics, and indeed we often refer to the state of the system \(\ |\psi\rangle\) as the “wave vector” or the “wave function.” Although we will not explore this statement in great detail in this course, it is correct to say that in quantum mechanics, particles often (but not always) behave more like waves than like particles. Different quantum states may interfere with each other in the same way that waves can interfere with each other. From this interference arises much of the non-intuitive nature of quantum mechanics.

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