Phy5646/Non-degenerate Perturbation Theory - Problem 3: Difference between revisions
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This example taken from "Quantum Physics" 3rd ed., Stephen Gasiorowicz, p. 177. | This example taken from "Quantum Physics" 3rd ed., Stephen Gasiorowicz, p. 177. | ||
'''Problem:''' | '''Problem:''' | ||
A charged particle in a simple harmonic oscillator, for which <math>{H}_0 = \frac{p^{2}}{2m} + \frac{mw^{2}}{2}</math>, | A charged particle in a simple harmonic oscillator, for which <math>{H}_0 = \frac{p^{2}}{2m} + \frac{mw^{2}}{2}</math>, | ||
subject to a constant electric field so that <math>{H}^' = q\mathcal{E} x</math>. Calculate the energy shift | subject to a constant electric field so that <math>{H}^' = q\mathcal{E} x</math>. Calculate the energy shift | ||
for the <math>n^{th}</math> level to first and second order in <math>(q\mathcal{E})</math>. | for the <math>n^{th}</math> level to first and second order in <math>(q\mathcal{E})</math>. | ||
(Hint: Use the operators <math>a</math> and <math>a^{\dagger}</math> for the evaluation of the matrix elements). | (Hint: Use the operators <math>a</math> and <math>a^{\dagger}</math> for the evaluation of the matrix elements). | ||
'''Solution:''' | |||
(a) To first order we need to calculate <math>{H}^' = q\mathcal{E} \langle n|x|n\rangle</math>. It is easy to show that (n[x|n) = 0. One way is to | |||
use the relation (7-4), from which we get | |||
h (A + A+) | |||
2mio | |||
and since A\n) = \fn\n — 1) and A+\n) = Vn + \\n + 1) we see that («|jc|«) = 0. Another way of | |||
seeing this is that the matrix element involves the integral | |||
CO CO | |||
J 0*(*W>„(jc) = J dxx\$n(x)\2 | |||
Since |</>„(jt)|2 is always an even function of x (</>„(— x) = (— l)"<£„(jt)), the integral from — °= to +» | |||
involving an odd integrand is zero. | |||
(b) The second-order term involves | |||
a^y \{k\x\n)\2 _q2%2 h \(k\A+A+\n)\2 | |||
ten hm(n — k) fuo 2mio ^n n — k | |||
The only contributions come from k = n — 1 and k = n + 1, so that | |||
\{k\A + A+\n)\2 _ |V^|2 | |V^TI|2 _ i | |||
ten n-k 1 -1 | |||
and thus | |||
9¾2 | |||
£(2) = | |||
2mu> | |||
The result is independent of n. We can check for its correctness by noting that the total potential | |||
energy is | |||
1 n co 1 J ? 24% \ I i( <&> Y 92¾2 | |||
— rruo x + q%x = ■= m<o\ xr H x I = -z ma>\ x H | |||
2 H 2 \ tm? I 2 V mco2/ 2rm>2 | |||
Thus the perturbation shifts the center of the potential by —q%/mco2 and lowers the energy by | |||
q2%2l2rmp-, which agrees with our second-order result. | |||
Revision as of 04:02, 3 April 2010
(Submitted by Team 1)
This example taken from "Quantum Physics" 3rd ed., Stephen Gasiorowicz, p. 177.
Problem: A charged particle in a simple harmonic oscillator, for which , subject to a constant electric field so that . Calculate the energy shift for the level to first and second order in . (Hint: Use the operators and for the evaluation of the matrix elements).
Solution: (a) To first order we need to calculate . It is easy to show that (n[x|n) = 0. One way is to use the relation (7-4), from which we get h (A + A+) 2mio and since A\n) = \fn\n — 1) and A+\n) = Vn + \\n + 1) we see that («|jc|«) = 0. Another way of seeing this is that the matrix element involves the integral CO CO J 0*(*W>„(jc) = J dxx\$n(x)\2 Since |</>„(jt)|2 is always an even function of x (</>„(— x) = (— l)"<£„(jt)), the integral from — °= to +» involving an odd integrand is zero. (b) The second-order term involves a^y \{k\x\n)\2 _q2%2 h \(k\A+A+\n)\2 ten hm(n — k) fuo 2mio ^n n — k The only contributions come from k = n — 1 and k = n + 1, so that \{k\A + A+\n)\2 _ |V^|2 | |V^TI|2 _ i ten n-k 1 -1 and thus 9¾2 £(2) = 2mu> The result is independent of n. We can check for its correctness by noting that the total potential energy is 1 n co 1 J ? 24% \ I i( <&> Y 92¾2 — rruo x + q%x = ■= m<o\ xr H x I = -z ma>\ x H 2 H 2 \ tm? I 2 V mco2/ 2rm>2 Thus the perturbation shifts the center of the potential by —q%/mco2 and lowers the energy by q2%2l2rmp-, which agrees with our second-order result.
