Difference between revisions of "Results of Stationary Perturbation Theory"

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:<math>
| n^{(1)}  \rangle  = \sum'_{m} \frac{| m \rangle  \langle  m | H^\prime | n {\rangle}}{E_n - E_m}
+
| n^{(1)}  \rangle  = \sum'_{m} \frac{| m^{(0)} \rangle  \langle  m^{(0)} | H^\prime | n^{(0)} {\rangle}}{E^{(0)}_n - E^{(0)}_m}
 
</math>
 
</math>
 
The symbol <math>\sum^\prime</math> indicates that the term <math>m = n</math> is
 
The symbol <math>\sum^\prime</math> indicates that the term <math>m = n</math> is

Revision as of 17:29, 1 February 2013

Review: Results of Stationary Perturbation Theory

For reference, we recapitulate some elementary results from perturbation theory. Assume that the Hamiltonian of a system may be written as the sum of two parts

and that the eigenstates and eigenvalues of are known:

If it is not possible to find the eigenvalues of exactly, it is possible to write power series expressions for them that converge over some interval. If is time independent, the problem is stationary and the appropriate perturbation theory is Rayleigh- Schrodinger stationary state perturbation theory, described in most texts in quantum mechanics. We write

and express the order perturbation in terms of and . The energies are given by

We shall only use the lowest two orders here. The first order results are

The symbol indicates that the term is excluded. It is understood that the sum extends over continuum states. Note that the state function is nor properly normalized, but that the error is quadratic in .

The second order results are

In second order perturbation theory the effect of a coupling of and by is to push the levels apart, independent of the value of . Consequently, states coupled by always repel each other.