Buried unstrained germanium channels: a lattice-matched platform for quantum technology

Abstract

Strained Ge (ε-Ge) and strained Si (ε-Si) buried quantum wells have enabled advanced spin-qubit quantum processors. However, in the absence of suitable lattice-matched substrates, ε-Ge and ε-Si are deposited on defective, metamorphic SiGe substrates, which may impact device performance and scaling. Here an alternative platform is introduced, based on the heterojunction between unstrained Ge and a lattice-matched strained SiGe (ε-SiGe) barrier, eliminating the need for metamorphic buffers altogether. In a structure with a 52-nm-thick ε-SiGe barrier, a low-disorder two-dimensional hole gas is demonstrated with a high-mobility of 1.33×105 cm2/Vs and a low percolation density of 1.4(1)×1010 cm-2. Quantum transport shows that holes confined in the buried unstrained Ge channel have a strong density-dependent in-plane effective mass and out-of-plane g-factor, pointing to a significant heavy-hole-light-hole mixing in agreement with theory. Measurements of Zeeman spin-split levels in quantum point contacts further highlight this character, showing a two-fold larger in-plane g-factor in Ge than in ε-Ge. The prospect of strong spin-orbit interaction, isotopic purification, and of hosting superconducting pairing correlations make this platform appealing for fast quantum hardware and hybrid quantum systems.