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

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

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

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.

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

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

In perturbation theory, what defines "small?" Question 1 options: a) The absolute size of the perturbation...

In perturbation theory, what defines "small?" Question 1 options: a) The absolute size of the perturbation is small. b) The size of the perturbation is small as compared to the main component. c) The perturbation must be smaller than the Heisenberg uncertainty limit. d) The perturbation should be smaller than 1 nanometer. e) The number of degenerate states

Calculate second-order energy correction to the ground state of a particle in a box for a...

Calculate second-order energy correction to the ground state of a particle in a box for a perturbation of the form H(1) = -ϵ sin ( πx/L) by using the closure approximation. Infer a value of ΔE depends on the perturbation and is not simply a characteristic of the system itself.

As you know, in the Schrodinger representation, the wavefunction is time-dependent while the operator is time-independent....

As you know, in the Schrodinger representation, the wavefunction is time-dependent while the operator is time-independent. In the Heisenberg representation, the wavefunction is time-independent while the operator is generally time-dependent. However, only the Hamiltonian is time-independent in both representations of Schrodinger and Heisenberg. Why? Describe the reason for that clearly.

Consider a time-independent wavefunction of a particle moving in three-dimensional space. Identify the variables upon which...

Consider a time-independent wavefunction of a particle moving in three-dimensional space. Identify the variables upon which the wavefunction depends.

Please type the answer (the process) clearly. Derive the time-independent Schroedinger’s equation for the asymmetric wavefunctions...

Please type the answer (the process) clearly. Derive the time-independent Schroedinger’s equation for the asymmetric wavefunctions of the finite potential well. Provide the wavefunctions and energy values in terms of ?.

1) Derive a time independent equation from the two Kinematic equations in FULLY REDUCED FORM. Show...

1) Derive a time independent equation from the two Kinematic equations in FULLY REDUCED FORM. Show all explicit steps. 2) True/False: Multiplying vectors together always produces a scalar. Always T. Always F. Conditional (explain).

Derive an expression for the rate of product production for the following (second-order) enzymatic reaction network:...

Derive an expression for the rate of product production for the following (second-order) enzymatic reaction network: E + A   ↔   E•A E•A + B   ↔   E•A•B E•A•B   ↔   P + E