Fermi energy and ratio of the number of occupied levels at an energy

acusanelli
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Homework Statement



a) Calculate the Fermi energy for copper.

b) Calculate the ratio of the number of occupied levels at an energy of 8.5 eV to the number occupied levels at the Fermi energy at room temperature.

c) Based on your answer to a) and b) above, show that at room temperature, the conduction electron gas must be treated as a quantum gas of indistinguishable particles


The Attempt at a Solution



I know that the fermi energy for copper is 7.0ev but have no idea how it was set up. please help me set this problem up with equations or whatever i need to solve it
 
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You will need to supply more info to solve (a). You will need to supply equations for the Fermi energy.
 
that was all i was given to work with
 
Well you will need more info to calculate the Fermi energy. Even if you assumed it to be a perfect fermi sea, you would need the density of carriers then.
 
well if i know the fermi energy for copper is 7ev then how do i set up and solve for b?
 
Look up the Fermi function. You will need that for (b) as well as the density of states.
 
Last edited:
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This figure is from "Introduction to Quantum Mechanics" by Griffiths (3rd edition). It is available to download. It is from page 142. I am hoping the usual people on this site will give me a hand understanding what is going on in the figure. After the equation (4.50) it says "It is customary to introduce the principal quantum number, ##n##, which simply orders the allowed energies, starting with 1 for the ground state. (see the figure)" I still don't understand the figure :( Here is...
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The last problem I posted on QM made it into advanced homework help, that is why I am putting it here. I am sorry for any hassle imposed on the moderators by myself. Part (a) is quite easy. We get $$\sigma_1 = 2\lambda, \mathbf{v}_1 = \begin{pmatrix} 0 \\ 0 \\ 1 \end{pmatrix} \sigma_2 = \lambda, \mathbf{v}_2 = \begin{pmatrix} 1/\sqrt{2} \\ 1/\sqrt{2} \\ 0 \end{pmatrix} \sigma_3 = -\lambda, \mathbf{v}_3 = \begin{pmatrix} 1/\sqrt{2} \\ -1/\sqrt{2} \\ 0 \end{pmatrix} $$ There are two ways...
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