Optical study of superconducting Ga-rich layers in silicon

Abstract

We performed phase-sensitive terahertz (0.12 - 1.2 THz) transmission measurements of Ga-enriched layers in silicon. Below the superconducting transition, Tc = 6.7 K, we find clear signatures of the formation of a superconducting condensate and of the opening of an energy gap in the optical spectra. The London penetration depth, λ(T), and the condensate density, ns = λ2 0)/λ2(T), as functions of temperature demonstrate behavior, typical for conventional superconductors with λ(0) = 1.8 μ m. The terahertz spectra can be well described within the framework of Eliashberg theory with strong electron-phonon coupling: the zero-temperature energy gap is 2(0) = 2.64 meV and 2(0)/kBTc = 4.6 0.1, consistent with the amorphous state of Ga. At temperatures just above Tc, the optical spectra demonstrate Drude behavior.