Put the standard imports for Matplotlib, Numpy and the IPython widgets in the following cell.
In [1]:
%matplotlib inline
import matplotlib.pyplot as plt
import numpy as np
In [2]:
from IPython.display import Image
from IPython.html.widgets import interact, interactive, fixed
In quantum statistics, the Fermi-Dirac distribution is related to the probability that a particle will be in a quantum state with energy $\epsilon$. The equation for the distribution $F(\epsilon)$ is:
In [3]:
Image('fermidist.png')
Out[3]:
In this equation:
In the cell below, typeset this equation using LaTeX:
Define a function fermidist(energy, mu, kT)
that computes the distribution function for a given value of energy
, chemical potential mu
and temperature kT
. Note here, kT
is a single variable with units of energy. Make sure your function works with an array and don't use any for
or while
loops in your code.
In [4]:
def fermidist(energy, mu, kT):
e = 2.71828182845904523536028747135266249775724709369995
"""Compute the Fermi distribution at energy, mu and kT."""
x = 1/(e **((energy - mu)/kT) + 1)
return x
In [5]:
assert np.allclose(fermidist(0.5, 1.0, 10.0), 0.51249739648421033)
assert np.allclose(fermidist(np.linspace(0.0,1.0,10), 1.0, 10.0),
np.array([ 0.52497919, 0.5222076 , 0.51943465, 0.5166605 , 0.51388532,
0.51110928, 0.50833256, 0.50555533, 0.50277775, 0.5 ]))
Write a function plot_fermidist(mu, kT)
that plots the Fermi distribution $F(\epsilon)$ as a function of $\epsilon$ as a line plot for the parameters mu
and kT
.
In [6]:
def plot_fermidist(mu, kT):
E = np.linspace(0, 10., 100)
y = plt.plot(E, fermidist(E, mu, kT))
plt.xlabel('t')
plt.ylabel('X(t)')
return y
In [7]:
plot_fermidist(4.0, 1.0)
Out[7]:
In [8]:
assert True # leave this for grading the plot_fermidist function
Use interact
with plot_fermidist
to explore the distribution:
mu
use a floating point slider over the range $[0.0,5.0]$.kT
use a floating point slider over the range $[0.1,10.0]$.
In [28]:
interact(plot_fermidist, mu = (0.0,5.0), kT=(.1,10.0));
Provide complete sentence answers to the following questions in the cell below:
Use LaTeX to typeset any mathematical symbols in your answer.
When kT is low, the probablity drops off very quickly after a certain point. When kT is high, the probability follows a negatively sloped line. Mu changes the height of the function.