For a particle in an infinite potential well the separation between energy states increases as n...

For a particle in an infinite potential well the separation between energy states increases as n increases (see Eq. 38-13). But doesn’t the correspondence principle require closer spacing between states as n increases so as to approach a classical (nonquantized) situation? Explain.

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genius_generous answered 2 years ago

Find the energy spectrum of a particle in the infinite square well, with potential U(x) →...

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Derive the general wavefunction for a particle in a box (i.e. the infinite square well potential)....

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particle of mass m, which moves freely inside an infinite potential well of length a, is...

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