Degenerate perturbation theory

AI Thread Summary
The discussion revolves around understanding the application of degenerate perturbation theory in quantum mechanics. The user seeks clarification on why a specific term in their solution is negative and the significance of the O(λ²) notation. It is explained that the negative sign arises from the eigenvalues of the perturbation matrix, which are plus and minus the modulus of λ, leading to non-degenerate states with different energies. The O(λ²) indicates that any additional corrections to energy will be of a higher order than λ. Ultimately, the ground state is identified as the state corresponding to the negative eigenvalue, which is -λ.
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Homework Statement


Hi, i have put the question, my attempt and actual answer in the attached picture. My answer is not quite right; firstly why is the second term a minus lambda, and where does the O(lamdba^2) come from?


Homework Equations





The Attempt at a Solution


 

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What are the two eigenvalues you found when you diagonalized the perturbation? You should have found two. Once you know both, I think you'll see why the minus sign is there in the answer.

The O(\lambda^2) just means that the any further correction to the energy is of order \lambda^2 or higher. There are no other corrections proportional to |\lambda|.
 
vela said:
What are the two eigenvalues you found when you diagonalized the perturbation? You should have found two. Once you know both, I think you'll see why the minus sign is there in the answer.

The O(\lambda^2) just means that the any further correction to the energy is of order \lambda^2 or higher. There are no other corrections proportional to |\lambda|.

Do you mean the plus and minus modulus (\lambda) for the two eigenvalues? If so how does that give the minus sign? Thanks
 
You found the eigenvalues of the perturbation matrix to be plus or minus modulus of lamdba. So, the initial two-fold degenerate state acted by the perturbation will no longer be degenerate it will give rise to two different states (eigenvectors in first order of H) with different energies. Which is now the groud state?
 
go quantum! said:
You found the eigenvalues of the perturbation matrix to be plus or minus modulus of lamdba. So, the initial two-fold degenerate state acted by the perturbation will no longer be degenerate it will give rise to two different states (eigenvectors in first order of H) with different energies. Which is now the groud state?

Ah, the groundstate is minus lamda. Thanks (to all)
 
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