First, here is some base-line discussion for Matlab and Python.
Now, for this homework, you basically need to calculate some functions and plot up the results. Example 2.3 of the textbook is a pretty good "template" for this task, and so I will discuss that example.
Here is the Matlab code for Example 2.3. This code is somewhat different from the code in the text book, but does the same thing.
%E2.3: Fermi Function Calculation, f(E-EF,T)
%Initialization
clear
close
%Constant
%25.85 meV for 300 K is an equivalent way to remember it.
k=8.617e-5;
%Google for "Matlab linspace", to find out what linspace does!
dE=linspace(-0.2,0.2);
for ii=1:4;
T=100*ii;
kT=k*T;
f(ii,:)=1./(1+exp(dE./kT));
end
%Plotting result
close
plot(dE,f); grid;
xlabel('E - E_F (eV)'); ylabel('f (E)');
text(.05,.22,'T=400K'); text(-.03,.12,'T=100K');
%Octave-specific -- uncomment this line for using with Octave.
%print -djpg E2.3.oct.jpg
The obtained images by Matlab and Octave are as follows. To run the above code with Octave, you can uncomment the last line, and then do
octave E2.3.oct.m
where octave must be in your path, and E2.3.oct.m is the assumed file name of the above code.
