Time independent perturbation theory

In summary, the matrix elements of W are comparable in magnitude to those of H0, with the exception that they are roughly the same as the difference between the eigenvalues of H0. This means that the values in the matrix W are approximately equal to the difference between the eigenvalues of H0. However, it is not specified which specific eigenvalues are being compared. This information is obtained from the SChaum's Outlines of Quantum Mechanics.
  • #1
cks
165
0
H=H0 + lambda * W

lambda << 1 must hold and the matrix elements of W are comparable in magnitude to those of H0.

More precisely, the matrix elements of W are of the same magnitude as the difference between the eigenvalues of H0.

I don't understand what is the meaning of " the matrix elements of W are of the same magnitude as the difference between the eigenvalues of H0".

(the above explanation are obtained from the SChaum's Outlines of Quantum Mechanics)
 
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  • #2
cks said:
H=H0 + lambda * W

lambda << 1 must hold and the matrix elements of W are comparable in magnitude to those of H0.

More precisely, the matrix elements of W are of the same magnitude as the difference between the eigenvalues of H0.

I don't understand what is the meaning of " the matrix elements of W are of the same magnitude as the difference between the eigenvalues of H0".

it means that the matrix elements (the entries in the matrix) are about that same size as the difference between that eigenvalues of H0.
 
  • #3
What exactly is it that you don't understand? Are you having trouble understanding what exactly those matrix elements are and why they are called matrix elements or is it something else?
 
  • #4
the matrix elements of W are of the same magnitude as the difference between the eigenvalues of H0".

Let's say the matrix W=[2.2 3.1 4.1; 4.1 5.3 6.0; 7.3 8.2 9.3] (matlab code)

let's say the eigenvalues of H0 are 1 2 3 4 5 6 7 8 9

the matrix element 2.2 is roughly the same as the difference of the eigenvalues of 3-1. Am I understanding this correctly?

the matrix elements of W are of the "same magnitude"(don't understand what same magnitude means?) as the difference(difference? difference between which eigenvalues, in my example, there are 9 eigenvalues, which minus which is the difference the author is talking?) between the eigenvalues of H0".
 

What is time independent perturbation theory?

Time independent perturbation theory is a mathematical technique used in quantum mechanics to approximate the energy levels and wavefunctions of a quantum system when it is subject to a small perturbation or disturbance, without explicitly solving the Schrödinger equation for the perturbed system.

How does time independent perturbation theory work?

Time independent perturbation theory works by breaking down the Hamiltonian of the perturbed system into a sum of two Hamiltonians: the unperturbed Hamiltonian, which describes the system without any perturbation, and a small perturbation Hamiltonian. The perturbation is then treated as a small correction to the unperturbed system, and a series expansion is used to calculate the energy levels and wavefunctions of the perturbed system.

What are the limitations of time independent perturbation theory?

Time independent perturbation theory is limited to small perturbations, as the series expansion used to approximate the energy levels and wavefunctions only converges for small perturbations. It also assumes that the perturbation is time independent, meaning it does not change over time. Additionally, it does not take into account the effects of degeneracy, where multiple energy levels have the same energy.

What are the applications of time independent perturbation theory?

Time independent perturbation theory has many applications in quantum mechanics, including calculating the energy levels and wavefunctions of atoms, molecules, and other quantum systems. It is also used in the study of quantum field theory and solid state physics, and has practical applications in fields such as chemistry and materials science.

What is the difference between time independent and time dependent perturbation theory?

The main difference between time independent and time dependent perturbation theory is that time independent perturbation theory assumes that the perturbation is time independent, while time dependent perturbation theory accounts for time-dependent perturbations. Time dependent perturbation theory is more complex and can be used to study systems that undergo significant changes over time, while time independent perturbation theory is limited to small perturbations and assumes that the system remains in a steady state.

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