We theoretically study the dependency of the superconductivity transition critical temperature (TC) on the electron and exciton-polariton densities in layered systems, where superconductivity is mediated by a Bose-Einstein condensate of exciton-polaritons. The critical temperature increases with the polariton density, but decreases with the electron gas density, surprisingly. This makes doped semiconductor structures with shallow Fermi energies better adapted for observation of the exciton-polariton-induced superconductivity than metallic layers. For realistic GaAs-based microcavities containing doped and neutral quantum wells we estimate Tc as close to 50 K. Superconductivity is suppressed by magnetic fields of the order of 4 T due to the Fermi surface renormalization.
Superconductivity in semiconductor structures: The excitonic mechanism
2016
Abstract
We theoretically study the dependency of the superconductivity transition critical temperature (TC) on the electron and exciton-polariton densities in layered systems, where superconductivity is mediated by a Bose-Einstein condensate of exciton-polaritons. The critical temperature increases with the polariton density, but decreases with the electron gas density, surprisingly. This makes doped semiconductor structures with shallow Fermi energies better adapted for observation of the exciton-polariton-induced superconductivity than metallic layers. For realistic GaAs-based microcavities containing doped and neutral quantum wells we estimate Tc as close to 50 K. Superconductivity is suppressed by magnetic fields of the order of 4 T due to the Fermi surface renormalization.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
