(a) Write down: (i) The Hamiltonian operator, H (where H = T + V), for a general potential V (x). (ii) The operator for momentum, p. (b) Evaluate the commutator [H, pl of these operators and comment on the significance of the result. (c) How would your result for (b) be affected if V (x) = 0, i.e. for a free particle? (d) It can be shown that the time evolution of the expectation value (O) of an observ- able represented by some general operator Ô is given by (O)P dt where Ĥ is the Hamiltonian operator you wrote down in part (a) and [H,Ô] is the commutator of the operators H and Ô. Use this result and the commutator you obtained in part (b) to show that d (p) dV(x)' dt dr which is special case of Ehrenfest's Theorem. What is the significance of this result?
(a) Write down: (i) The Hamiltonian operator, H (where H = T + V), for a general potential V (x). (ii) The operator for momentum, p. (b) Evaluate the commutator [H, pl of these operators and comment on the significance of the result. (c) How would your result for (b) be affected if V (x) = 0, i.e. for a free particle? (d) It can be shown that the time evolution of the expectation value (O) of an observ- able represented by some general operator Ô is given by (O)P dt where Ĥ is the Hamiltonian operator you wrote down in part (a) and [H,Ô] is the commutator of the operators H and Ô. Use this result and the commutator you obtained in part (b) to show that d (p) dV(x)' dt dr which is special case of Ehrenfest's Theorem. What is the significance of this result?
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