Valley Splittings in Si/SiGe Heterostructures from First Principles

Abstract

We compute valley splittings in Si/SiGe superlattices using ab initio density functional theory (DFT). This first-principle approach is expected to provide an excellent description of interfaces, strains, and atomistic disorder without empirically fitted parameters. We benchmark atomistic tight-binding (TB) and the ``2k0'' theory within the effective mass (EM) approximation against DFT. We show that DFT supports the main conclusions of the 2k0 theory, but reveals some limitations of semi-empirical methods such as the EM and TB, in particular about the description of atomistic disorder. The DFT calculations also highlight the effects of strong valley-orbit mixing at large valley splittings. Nevertheless, TB and the 2k0 theory shall provide reasonable valley splitting statistics in many heterostructures of interest for spin qubit devices.

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