Author: Tru Physics

Problem 2.9 For the wave function in Example 2.2, find the expectation value ofH, at time t=0, the “old fashioned” way: Compare the result we got in Example 2.3. Note: Because is independent of time, there is no loss of generality in using t=0. Solution: Problem 2.9 Solution (Download)

Problem 1.18 | Griffith’s Intro to QM | Solutions

Problem 1.16 A particle is represented (at time ) by the wave function (a) Determine the normalization constant A.(b) What is the expectation value of x?(c) What is the expectation value of p? (Note that you cannot get it from . Why not?)(d) Find the expectation value of .(e) Find the expectation value of .(f)…

Problem 1.14 Let be the probability of finding the particle in the range , at time t.(a) Show that where What are the units of ? Comment: J is called the probability current, because it tells you the rate at which probability is “flowing” past the point x. If is increasing, then more probability is…

Problem 3.9 (a) Cite a Hamiltonian from Chapter 2 (other than the harmonic oscillator) that has only a discrete spectrum.(b) Cite a Hamiltonian from Chapter 2 (other than the free particle) that has only a continuous spectrum.(c) Cite a Hamiltonian from Chapter 2 (other than the finite square well) that has both a discrete and…

Problem 3.7 (a) Suppose that and are two eigenfunctions of an operator , with the same eigenvalue q. Show that any linear combination of f and g is itself an eigenfunction of , with eigenvalue q.(b) Check that and are eigenfunctions of the operator , with the same eigenvalue. Construct two linear combinations of f…

Problem 3.6 Consider the operator , where (as in Example 3.1) is the azimuthal angle in polar coordinates, and the functions are subject to Equation 3.26. Is hermitian? Find its eigenfunctions and eigenvalues. What is the spectrum of ? Is the spectrum degenerate? Solution: Problem 3.6 Solution (Download)

Problem 3.4 (a) Show that the sum of two hermitian operators is hermitian.(b) Suppose is hermitian, and is a complex number. Under what condition (on ) is hermitian?(c) When is the product of two hermitian operators hermitian?(d) Show that the position operator and the Hamiltonian operator are hermitian. Solution: Problem 3.4 Solution (Download)

Problem 3.5 (a) Find the hermitian conjugates of x, i, and .(b) Show that (note the reversed order), and for a complex number c.(c) Construct the hermitian conjugate of (Equation 2.48). Solution: Problem 3.5 Solution (Download)