Tag: Griffith’s Introduction to Quantum Mechanics 3rd Edition
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Problem 7.3 – Griffith’s Intro to QM
Problem 7.3 Two identical spin-zero bosons are placed in an infinite square well (Equation 2.22). They interact weakly with one another, via the potential (where is a constant with the dimensions of energy, and is the width of the well). (a) First, ignoring the interaction between the particles, find the ground state and the first…
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Problem 7.2 – Griffith’s Intro to QM
Problem 7.2 For the harmonic oscillator , the allowed energies are where is the classical frequency. Now suppose the spring constant increases slightly: . (Perhaps we cool the spring, so it becomes less flexible.) (a) Find the exact new energies (trivial, in this case). Expand your formula asa power series in , up to second…
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Problem 7.1 – Griffith’s Intro to QM
Problem 7.1 Suppose we put a delta-function bump in the center of the infinite square well: where is a constant. (a) Find the first-order correction to the allowed energies. Explain why the energies are not perturbed for even n. (b) Find the first three nonzero terms in the expansion (Equation 7.13) of the correction to…
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Problem 5.5 – Griffith’s Intro to QM
Problem 5.5 (a) Write down the Hamiltonian for two noninteracting identical particles in the infinite square well. Verify that the fermion ground state given in Example 5.1 is an eigenfunction of , with the appropriate eigenvalue. (b) Find the next two excited states (beyond the ones given in the example)—wave functions, energies, and degeneracies—for each…
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Problem 5.4 – Griffith’s Intro to QM
Problem 5.4 (a) If and are orthogonal, and both are normalized, what is the constant in Equation 5.17? (b) If (and it is normalized), what is ? (This case, of course, occurs only for bosons.) Solution: Problem 5.4 Solution (Download)
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Problem 5.3 – Griffith’s Intro to QM
Problem 5.3 Chlorine has two naturally occurring isotopes, and Show that the vibrational spectrum of HCl should consist of closely spaced doublets, with a splitting given by , where is the frequency of the emitted photon. Hint: Think of it as a harmonic oscillator, with where is the reduced mass (Equation 5.15) and is presumably…
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Problem 5.2 – Griffith’s Intro to QM
Problem 5.2 In view of Problem 5.1, we can correct for the motion of the nucleus in hydrogen by simply replacing the electron mass with the reduced mass. (a) Find (to two significant digits) the percent error in the binding energy of hydrogen (Equation 4.77) introduced by our use of instead of (b) Find the…
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Problem 4.5 – Griffith’s Intro to QM
Problem 4.5 Show that satisfies the equation (Equation 4.25), for . This is the unacceptable “second solution”—what’s wrong with it? Solution: Problem 4.5 Solution (Download)
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Problem 4.4 – Griffith’s Intro to QM
Problem 4.4 Use Equations 4.27, 4.28, and 4.32, to construct and . Check that they are normalized and orthogonal. Solution: Problem 4.4 Solution (Download)
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Problem 4.2 – Griffith’s Intro to QM
Problem 4.2 Use separation of variables in cartesian coordinates to solve the infinite cubical well (or “particle in a box”): (a) Find the stationary states, and the corresponding energies. (b) Call the distinct energies , in order of increasing energy. Find , and . Determine their degeneracies (that is, the number of different states that…