Valence band structure calculations of strained Ge1-xSnx quantum well pFETs

Abstract

The dependence of valence band structures of Ge1-xSnx with 0 ≤ x ≤ 0.2 on Sn content, biaxial strain, and substrate orientation is calculated using the nonlocal empirical pseudopotential method. The first valence subband structure in p-type Ge cap/fully strained Ge1-xSnx quantum well/Ge (001) and (111) inversion layers are theoretically studied using the 6×6 k·p model. A wave-function coupling of a Ge cap with respect to a strained Ge1-xSnx quantum well, which is influenced by the cap thickness, valence band offset, and confined effective mass, changes the energy dispersion relation in the two-dimensional k-space. The increase in Sn content and the decrease in cap thickness increase the hole population in the strained Ge1-xSnx quantum well to reduce the transport effective mass at the zone center in the Ge/strained Ge1-xSnx/Ge inversion layers.