Calculating Average Values and Proving Inequality for Particle Potential - N^nX

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SUMMARY

The discussion centers on applying the Virial Theorem to a particle with a potential of the form \(\lambda X^n\) and a Hamiltonian defined as \(H = \frac{P^2}{2m} + V(x)\). The key finding is that the average values of kinetic energy and potential energy satisfy the relationship \(2 = n\). The commutator of the Hamiltonian and the operator \(XP\) is given as \(i\hbar(n\lambda X^n - \frac{P^2}{m})\), which is crucial for deriving the average values.

PREREQUISITES
  • Understanding of the Virial Theorem in classical mechanics.
  • Familiarity with Hamiltonian mechanics and the structure of Hamiltonians.
  • Knowledge of commutation relations in quantum mechanics.
  • Proficiency in calculating time averages and limits in quantum systems.
NEXT STEPS
  • Study the application of the Virial Theorem in quantum mechanics.
  • Learn about the Heisenberg equations of motion and their implications.
  • Explore the derivation of average values in quantum mechanics.
  • Investigate the significance of commutators in quantum operator dynamics.
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Students and researchers in quantum mechanics, particularly those focusing on Hamiltonian systems and the application of the Virial Theorem to particle dynamics.

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[SOLVED] Virial Theorem

Homework Statement


A particle has a potential \lambda X^n and Hamiltonian H = \frac{P^2}{2m} + V(x)

Knowing that the commutator of H and XP is i\hbar(n\lambda X^n - \frac{P^2}{m}), find the average values <T> and <V> and verify that they satisfy:

2&lt;T&gt;=n&lt;V&gt;


Homework Equations





The Attempt at a Solution



The question asked to calculate the commutator and that is what I found, but I'm lost as to how to get the average values and proove the inequality.
 
Last edited:
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The question doesn't actually ask you to calculate the commutator; it gives you the value of the commutator (though with a sign error; it should read ...-P^2/m).

The next step is to recall what the commutator of any operator with the Hamiltonian gives you (Hint: Heisenberg EoM). After that you just have to take the time average on both sides, and take the limit of loooong times.
 
Last edited:
The question asked to calculate the [H, XP] commutator, I just didn't write it because I already found it and wanted to save time.

I'm not sure I understand the hint.
 
For an operator A, that is not explicitly time-dependent, (i\hbar) dA/dt is equal to a commutator. Does that help jog your memory?
 
Thank you! I solved the problem.
 

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