Using perturbation theory, find the energy of two coupled harmonic oscillators.

Consider a one dimensional Harmonic oscillator. Use perturbation theory to find the energy corrections up to...

Consider a one dimensional Harmonic oscillator. Use perturbation theory to find the energy corrections up to second order in the perturbative parameter ? for a perturbative potential of the kind: a) V = ?x b) V = ?x^3.

1. time-independent perturbation theory derive first-order For wavefunction and energy

1. time-independent perturbation theory derive first-order For wavefunction and energy

1. time-independent perturbation theory derive second-order for wavefunction and energy

1. time-independent perturbation theory derive second-order for wavefunction and energy

A system of 6 identical 1-dimensional harmonic oscillators (it could be two atoms of an Einstein...

A system of 6 identical 1-dimensional harmonic oscillators (it could be two atoms of an Einstein model solid). What is the probability that the first oscillator has 2 quanta of vibrational energy when the system has 3 quanta of vibrational energy? Hint: You may find it useful to consider how many microstates the system has and how many microstates the rest of the system has when the first oscillator has 2 quanta. Answer is 5/56 For the system considered in...

Let's look at N one-dimensional harmonic oscillators that are indistinguishable from each other in a microcanonical...

Let's look at N one-dimensional harmonic oscillators that are indistinguishable from each other in a microcanonical ensemble. If the mass is m and the frequency is w, use Hamiltonian. (1) Find the number of states whose energy is between E and E + ΔE through integration, then approximate the entropy from it. (2) Find the relationship between energy and temperature and the relationship between pressure and temperature.

Two different simple harmonic oscillators have the same natural frequency (f=2.00 Hz) when they are on...

Two different simple harmonic oscillators have the same natural frequency (f=2.00 Hz) when they are on the surface of the Earth. The first oscillator is a pendulum, the second is a vertical spring and mass. If both systems are moved to the surface of the moon (g=1.67 m/s2), what is the new frequency of the vertical spring and mass?

derive energy of harmonic oscillator using power series method

derive energy of harmonic oscillator using power series method

a) For a 1D linear harmonic oscillator find the first order corrections to the ground state...

a) For a 1D linear harmonic oscillator find the first order corrections to the ground state due to the Gaussian perturbation. b) Find the first order corrections to the first excited state. Please show all work.

2. (a) Find the entropy of a set of N oscillators of frequency ω as a...

2. (a) Find the entropy of a set of N oscillators of frequency ω as a function of the total quantum number n. Using the multiplicity function, g(N, n) = (N + n − 1)! n!(N − 1)! and make the Stirling approximation logN! ≈ NlogN − N. Replace N − 1 by N. (5 points)

A harmonic oscillator with the usual PE of V(x)= (.5)kx^2 perturbed by a small change to...

A harmonic oscillator with the usual PE of V(x)= (.5)kx^2 perturbed by a small change to the spring constant k -->(1+E)k, with E<<1. 1. Write the new energy eigenvalues, making sure any parameters are clearly defined. 2. Expand the eigenvalue expression in a power series in E up to the second order using a Taylor series expansion. 3. What is the perturbation Hamiltonian in the problem?