Calculating Expectation Values and Uncertainties in Quantum Mechanics

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SUMMARY

The discussion focuses on calculating expectation values and uncertainties for a particle in a one-dimensional box in its first excited state. The expectation values calculated are [x] = 0, [p] = 0, and [E] = (h_bar * pi^2 * n^2) / (2 * m * a^2). The uncertainties delta(x), delta(p), and delta(E) require the calculation of six expectation values, with delta(E) being zero due to the stationary state of the system. The relationship delta(x) = h_bar / sqrt(2m(V0 - E)) is suggested for approximating uncertainties.

PREREQUISITES
  • Understanding of quantum mechanics principles, particularly wave functions
  • Familiarity with expectation value calculations in quantum systems
  • Knowledge of the uncertainty principle in quantum mechanics
  • Basic proficiency in calculus for evaluating integrals
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  • Study the derivation of expectation values in quantum mechanics using wave functions
  • Learn about the uncertainty principle and its implications in quantum systems
  • Explore the concept of variance in quantum mechanics for calculating uncertainties
  • Investigate the significance of stationary states in quantum mechanics and their properties
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Students and professionals in physics, particularly those studying quantum mechanics, as well as educators looking to enhance their understanding of expectation values and uncertainties in quantum systems.

ynuo
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Homework Statement



Assume that a particle in a one-dimensional box is in its first excited state. Calculate the expectation values [x], [p], and [E], and the uncertainties
delta(x), delta(p), and delta(E). Verify that delta(x)*delta(p)>=h_bar/2.

Homework Equations



Psi=sqrt(2/a) cos(pi*x/a) e^(-i*E*t/h_bar)

[x]=Int(Psi_star x Psi, -a/2, a/2)

[p]=Int(Psi_star (-i*h_bar*d/dx) Psi, -a/2, a/2)

[E]=Int(Psi_star (i*h_bar*d/dt) Psi, -a/2, a/2)

The Attempt at a Solution



After evaluating the above integrals, I get:

[x]=0

[p]=0

[E]=h_bar*pi^2*n^2 / 2*m*a^2

I am trying to calculate the quantities delta(x), delta(p), and delta(E) but I am having trouble doing that. Can you please suggest some hints on how to proceed. Thank you.
 
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What are the definitions of delta(x) and delta(p) in terms of expectation values?
 
This is a trivial question, but would I be able to approximate it using the relations:

delta(x)=h_bar/sqrt(2m(V0 - E))
 
ynuo said:
This is a trivial question, but would I be able to approximate it using the relations:

delta(x)=h_bar/sqrt(2m(V0 - E))

That's a new relation to me. Just look at the definition of the variance and follow the prescription.
 
StatMechGuy said:
That's a new relation to me. Just look at the definition of the variance and follow the prescription.

Yep. You need to calculate six expectation values in order to calculate deltax, deltap and deltaE, and only three of them are <x>, <p> and <E>.
 
Do you know a reason why \Delta E is zero for this problem ? Besides the actual computation of it, which can be avoided by knowing this reason.
 

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