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Pick four out of six problems below. Students who try to solve all six problems will be given extra credit.

Problem 1

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Problem 2

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Problem 3

{\bf Classical point contact conductance:} The Sharvin formula for the electrical conductance of an extremely short contact area ${\displaystyle A}$ between two pieces of metal is given by

${\displaystyle G={\frac {2e^{2}}{h}}{\frac {k_{F}^{2}A}{4\pi }}}$

where ${\displaystyle k_{F}}$ is the Fermi wavelength. Derive the Sharvin formula by considering the total current flowing through a hole of area $A$ in a thin insulating barrier separating two free electron gases with different Fermi energies---the gas on the left has Fermi energy $\varepsilon_F^0 + eV$, while the gas on the right has Fermi energy $\varepsilon_F^0$, where $V$ is the applied voltage bias. Use purely macroscopic arguments.

In a free electron gas, the number of electrons with energies between ${\displaystyle E}$ and ${\displaystyle E+dE}$ traveling at an angle between ${\displaystyle \theta }$ and ${\displaystyle \theta +d\theta }$ with respect to a given axis is

${\displaystyle {\frac {\partial ^{2}n}{\partial E\partial \theta }}dEd\theta ={\frac {g(E)}{2}}\sin \theta d\theta dE}$,

where ${\displaystyle g(E)}$ is the density of states in three dimensions.

Problem 4

{\bf Quantum point contact conductance:} When the size of the contact from Problem 3 becomes comparable to Fermi wavelength ${\displaystyle \lambda _{F}=2\pi /k_{F}}$, the contact enters the quantum regime where its conductance follows from the Landauer formula:

${\displaystyle G={\frac {2e^{2}}{h}}N}$

where ${\displaystyle N}$ is the number of "conducting channels" assumed to have perfect transmission ${\displaystyle T=1}$ in ballistic transport. Find resistance in Ohm of such contact modeled by a two-dimensional wire (joining the macroscopic reservoirs) in the form of a strip of width ${\displaystyle W=1.75\lambda _{F}}$. Assume that conduction electrons in the wire can be described by the free-particle Schrodinger equation with the Dirichlet [i.e., ${\displaystyle \Psi ({\bf {r}})=0}$] boundary conditions along the lateral edges of the strip.