PHY6937: Difference between revisions

Welcome to Phy 6937 Superconductivity and superfluidity

PHY6937 is a one semester advanced graduate level course. Its aim is to introduce concepts and theoretical techniques for the description of superconductors and superfluids. This course is a natural continuation of the "many-body" course PHY5670 and will build on the logical framework introduced therein, i.e. broken symmetry and adiabatic continuity. The course will cover a range of topics, such as the connection between the phenomenological Ginzburg-Landau and the microscpic BCS theory, Migdal-Eliashberg treatment of phonon mediated superconductivity, unconventional superconductivity, superfluidity in He-4 and He-3, and Kosterlitz-Thouless theory of two dimensional superfluids.

The key component of the course is the collaborative student contribution to the course Wiki-textbook. Each team of students is responsible for BOTH writing the assigned chapter AND editing chapters of others.

Team assignments: Spring 2011 student teams

Outline of the course:

Pairing Hamiltonian and BCS instability

We can write the Hamiltonian of the system as:

${\displaystyle H=\sum _{\vec {r}}[\psi _{\sigma }^{\dagger }({\vec {r}})(\epsilon _{\vec {p}}-\mu )\psi _{\sigma }^{\dagger }({\vec {r}})+g\psi _{\uparrow }^{\dagger }({\vec {r}})\psi _{\downarrow }^{\dagger }({\vec {r}})\psi _{\downarrow }({\vec {r}})\psi _{\uparrow }({\vec {r}})]}$

where ${\displaystyle g<0}$ and ${\displaystyle |g|<<\epsilon _{F}}$.

For this system, the partition function is:

${\displaystyle Z=\int D[\psi _{\sigma }^{*}(\tau ,{\vec {r}}),\psi _{\sigma }(\tau ,{\vec {r}})]e^{-S_{BCS}}}$

where ${\displaystyle S_{BCS}=\int _{0}^{\beta }d\tau \sum _{\vec {r}}[\psi _{\sigma }^{\dagger }(\tau ,{\vec {r}})(\partial _{\tau }+\epsilon _{\vec {p}}-\mu )\psi _{\sigma }^{\dagger }({\vec {r}})+g\psi _{\uparrow }^{\dagger }({\vec {r}})\psi _{\downarrow }^{\dagger }({\vec {r}})\psi _{\downarrow }({\vec {r}})\psi _{\uparrow }({\vec {r}})]}$

It doesn't matter to multiply partition function by a constant:

${\displaystyle Z\rightarrow Z=\int D[\psi _{\sigma }^{*}(\tau ,{\vec {r}}),\psi _{\sigma }(\tau ,{\vec {r}})]D[\Delta ^{*}(\tau ,{\vec {r}}),\Delta (\tau ,{\vec {r}})]e^{-S_{BCS}-S_{\Delta }}}$

where ${\displaystyle S_{\Delta }=-\int _{0}^{\beta }d\tau \sum _{\vec {r}}{\frac {1}{g}}\Delta ^{*}(\tau ,{\vec {r}})\Delta (\tau ,{\vec {r}})}$

${\displaystyle \psi ^{\dagger }}$ and ${\displaystyle \psi }$ are grassmann numbers. ${\displaystyle \Delta ^{*}}$ and ${\displaystyle \Delta }$ are constant. ${\displaystyle \psi _{\uparrow }\psi _{\downarrow }}$ and ${\displaystyle \psi _{\downarrow }\psi _{\uparrow }}$ behave like constant.

Let's make a shift of the constant:

${\displaystyle \Delta \rightarrow \Delta +g\psi _{\uparrow }\psi _{\downarrow }}$

${\displaystyle \Delta ^{*}\rightarrow \Delta ^{*}+g\psi _{\downarrow }^{\dagger }\psi _{\uparrow }^{\dagger }}$

Then, ${\displaystyle S_{\Delta }=-\int _{0}^{\beta }d\tau \sum _{\vec {r}}{\{{\frac {1}{g}}\Delta ^{*}\Delta +\Delta ^{*}\psi _{\uparrow }\psi _{\downarrow }\Delta \psi _{\downarrow }^{\dagger }\psi _{\uparrow }^{\dagger }+g\psi _{\downarrow }^{\dagger }\psi _{\uparrow }^{\dagger }\psi _{\uparrow }\psi _{\downarrow }}\}}$

${\displaystyle {\begin{aligned}S&=S_{BCS}+S_{\Delta }\\&=\int _{0}^{\beta }d\tau \sum _{\vec {r}}\{\psi _{\sigma }^{\dagger }(\tau ,{\vec {r}})(\partial _{\tau }+\epsilon _{\vec {p}}-\mu )\psi _{\sigma }^{\dagger }(\tau ,{\vec {r}})\rightarrow S_{0}\\&+\Delta ^{*}(\tau ,{\vec {r}})\psi _{\uparrow }(\tau ,{\vec {r}})\psi _{\downarrow }(\tau ,{\vec {r}})\Delta (\tau ,{\vec {r}})\psi _{\downarrow }^{\dagger }(\tau ,{\vec {r}})\psi _{\uparrow }^{\dagger }(\tau ,{\vec {r}})\rightarrow S_{int}\\&-{\frac {1}{g}}\Delta ^{*}(\tau ,{\vec {r}})\Delta (\tau ,{\vec {r}})\}\rightarrow S_{\Delta }\end{aligned}}}$

then, ${\displaystyle Z=\int D[\psi _{\sigma }^{*}(\tau ,\mathbf {r} ),\psi _{\sigma }(\tau ,\mathbf {r} )]D[\Delta ^{*}(\tau ,\mathbf {r} ),\Delta (\tau ,\mathbf {r} )]e^{-(S_{0}+S_{int.}+S_{\Delta })}}$

Microscopic derivation of the Giznburg-Landau functional

Little Parks experiment