Electrical control of g-factors in a few-hole silicon nanowire MOSFET
arXiv:1511.08003 · doi:10.1021/acs.nanolett.5b02920
Abstract
Hole spins in silicon represent a promising yet barely explored direction for solid-state quantum computation, possibly combining long spin coherence, resulting from a reduced hyperfine interaction, and fast electrically driven qubit manipulation. Here we show that a silicon-nanowire field-effect transistor based on state-of-the-art silicon-on-insulator technology can be operated as a few-hole quantum dot. A detailed magnetotransport study of the first accessible hole reveals a g-factor with unexpectedly strong anisotropy and gate dependence. We infer that these two characteristics could enable an electrically-driven g-tensor-modulation spin resonance with Rabi frequencies exceeding several hundred MHz.
15 pages, 3 figures