Answer to Question #167703 in Quantum Mechanics for Sherine Horo

The wave function of a classical system should have a form "\\Psi = a e^{i\\phi}" with "a" a function that is changing very slowly (as classical mechanics are deterministic), the phase function is related to the action in the classical case as "S=\\phi\\cdot \\hbar" by analogy with the classical optics (Fermat's principe). Now by inserting this form of "\\Psi" in the Schrodinger's equation we get

"a \\partial_t S-i\\hbar \\partial_t a + \\frac{a}{2m} (\\nabla S)^2 - \\frac{i\\hbar}{2m}a\\Delta S-\\frac{i\\hbar}{m}\\nabla S \\nabla a - \\frac{\\hbar}{2m}\\Delta a + Va=0"

Now by writing separate equations for the real and imaginary parts (as a and S are real) we get:

"\\partial_t S + \\frac{1}{2m}(\\nabla S)^2+V-\\frac{\\hbar^2}{2ma} \\Delta a=0"

"\\partial_t a + \\frac{a}{2m} \\Delta S + \\frac{1}{m} \\nabla S \\nabla a=0"

The first equation in the limit "\\hbar \\to 0" gives us the Hamilton-Jacobi equation that describes the classical mechanics.

The second equation defines classical velocity in the terms of quantum mechanics.

The reference of these calculations is Landau, Lifshitz Quantum Mechanics: Non-Relativistic Theory. Vol. 3.