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apollonschild
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Homework Statement
It's an old assignment for exam, but the solution manual gives little help:
Describing a particle of mass m moving in one dimension (x) the wave function at time t=0 is:
## \Psi(x,t=0) = A \frac{1}{\sqrt{(x-x_0)^4 + l^4}} ##
##x_0## and ##l## are positive constants describing some length (##x_0, l>0##).
Normalize the wave equation and find the expectation value of x.
These integrals can be helpful (given with the assignment):
(all integrals are from -∞ to ∞, I'm just a tad new at texing, and you'll get it right)
## \int \frac{1}{x^2+l^2} dx = \frac{\pi}{l} ##
## \int \frac{1}{sqrt{x^4+l^4}} dx = \frac{3.7081}{l} ##
## \int \frac{1}{x^4+l^4} dx = \frac{\pi}{\sqrt{2}l^3} ##
I am having trouble mathematically or principally calculate the expectation value.
Homework Equations
Normalization demands ## 1 = < \Psi | \Psi > ##
Exceptation value is ## <x> = < \Psi | x \Psi > ##
The Attempt at a Solution
Normalizing the function was all right; since the function is symmetrical around ##x_0##, we can choose the function to be symmetric around zero, and so:
## 1 = |A|^2 \int \frac{1}{x^4+l^4} dx = |A|^2 \frac{\pi}{\sqrt{2}l^3} ##
So then ## A = \frac{\sqrt[4]{2}\sqrt{l^3}}{\sqrt{\pi}} ## or ## A = \sqrt[4]{2} \sqrt{\frac{l^3}{\pi}} ## if you like..
For the expectation value I'm not sure why it's "obviously" ##x_0##. I tried setting it up mathematically:
##<x> = |A|^2 \int \frac{x}{(x-x_0)^4+l^4} dx##
But I can't see how to get there (or really anywhere). My teacher suggests the same "substitution" as before (setting ##x_0 = 0##) to get:
##<x> = |A|^2 \int \frac{x}{(x-x_0)^4+l^4} dx = |A|^2 \int \frac{x}{x^4+l^4} dx + x_0 |A|^2 \int \frac{1}{x^4+l^4} dx ##
But I'm not following how like, what is the last part? And if I were to try and substitute like before, the variable would disappear, so I don't get his point.
I hop I TeXed everything correct. Welp pwease :-)