English

Piezoresistance in defect-engineered silicon

Applied Physics 2021-02-03 v3 Disordered Systems and Neural Networks Materials Science

Abstract

The steady-state, space-charge-limited piezoresistance (PZR) of defect-engineered, silicon-on-insulator device layers containing silicon divacancy defects changes sign as a function of applied bias. Above a punch-through voltage (VtV_t) corresponding to the onset of a space-charge-limited hole current, the longitudinal 110\langle 110 \rangle PZR π\pi-coefficient is π65×1011\pi \approx 65 \times 10^{-11}~Pa1^{-1}, similar to the value obtained in charge-neutral, p-type silicon. Below VtV_t, the mechanical stress dependence of the Shockley-Read-Hall (SRH) recombination parameters, specifically the divacancy trap energy ETE_T which is estimated to vary by 30\approx 30~μ\muV/MPa, yields π25×1011\pi \approx -25 \times 10^{-11}~Pa1^{-1}. The combination of space-charge-limited transport and defect engineering which significantly reduces SRH recombination lifetimes makes this work directly relevant to discussions of giant or anomalous PZR at small strains in nano-silicon whose characteristic dimension is larger than a few nanometers. In this limit the reduced electrostatic dimensionality lowers VtV_t and amplifies space-charge-limited currents and efficient SRH recombination occurs via surface defects. The results reinforce the growing evidence that in steady state, electro-mechanically active defects can result in anomalous, but not giant, PZR.

Keywords

Cite

@article{arxiv.2008.04788,
  title  = {Piezoresistance in defect-engineered silicon},
  author = {H. Li and A. Thayil and C. T. K. Lew and M. Filoche and B. C. Johnson and J. C. McCallum and S. Arscott and A. C. H. Rowe},
  journal= {arXiv preprint arXiv:2008.04788},
  year   = {2021}
}

Comments

9 pages, 8 figures

R2 v1 2026-06-23T17:46:55.262Z