derive energy of harmonic oscillator using power series method

Derive the equation of path for a 2D isotropic harmonic oscillator and explain Lissajous curves?

Derive the equation of path for a 2D isotropic harmonic oscillator and explain Lissajous curves?

The ground-state energy of a harmonic oscillator is 6 eV. If the oscillator undergoes a transition...

The ground-state energy of a harmonic oscillator is 6 eV. If the oscillator undergoes a transition from its n=3 to n=2 level by emitting a photon, what is the energy (in eV) of the emitted photon?

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?

5) Unlike the particle in the 1D box and the harmonic oscillator, the energy of the...

5) Unlike the particle in the 1D box and the harmonic oscillator, the energy of the ground state of the 2D rigid rotor is zero. What is the difference between these cases that allows the energy to be zero for the rigid rotor in 2D?

If I have a simple harmonic oscillator with an amplitude 4.2cm and has a total energy...

If I have a simple harmonic oscillator with an amplitude 4.2cm and has a total energy of 0.400J What would be the max speed of the the mass if the mass hanging on the oscillator is 3kg, and what is it's period of oscillation. Also, what is the kinetic energy of the entire system when the position of the oscillator is 0.850 cm from the center?

How would you solve the rate of energy dissipation of a damped simple harmonic oscillator?

How would you solve the rate of energy dissipation of a damped simple harmonic oscillator?

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and...

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and there are eight spin 1⁄2 particles in the oscillator. How much energy is needed to add a ninth electron. Explain and show your work.

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and...

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and there are eight spin-1/2 particles in the oscillator. How much energy is needed to add a ninth electron. Explain and show your work

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and...

A quantum mechanical simple harmonic oscillator has a 1st excited state with energy 3.3 eV and there are eight spin-1/2 particles in the oscillator. How much energy is needed to add a ninth electron. Explain and show your work

In Classical Physics, the typical simple harmonic oscillator is a mass attached to a spring. The...

In Classical Physics, the typical simple harmonic oscillator is a mass attached to a spring. The natural frequency of vibration (radians per second) for a simple harmonic oscillator is given by ω=√k/m and it can vibrate with ANY possible energy whatsoever. Consider a mass of 135 grams attached to a spring with a spring constant of k = 1 N/m. What is the Natural Frequency (in rad/s) of vibration for this oscillator? In Quantum Mechanics, the energy levels of a...