English

Electrically switchable vacancy state revealed by in-operando positron experiments

Materials Science 2026-04-24 v1 Applied Physics

Abstract

Whether the flash state in electrically driven solids involves non-equilibrium defect production or is accounted for by Joule heating alone has been debated since 2010. Using positron annihilation spectroscopy on copper, we observe a fully reversible, electrically switchable vacancy population: the DBS S-parameter rises above baseline whenever applied current exceeds a critical density and returns on current removal. Positron lifetime spectroscopy independently confirms open-volume defect formation and reveals a void to cluster relaxation hierarchy. The current-induced vacancy concentration exceeds the thermal-equilibrium value at 352C by > 106x, is present only while current is applied, and vanishes within minutes. The nucleation rate scales steeply with the applied current, connecting the minute-scale kinetics resolved here to the sub-second flash events observed in ceramic sintering. These results demonstrate current-induced Frenkel-pair production in a metal and identify a defect-mediated, non-equilibrium contribution to the flash state.

Keywords

Cite

@article{arxiv.2604.21283,
  title  = {Electrically switchable vacancy state revealed by in-operando positron experiments},
  author = {Ric Fulop and Laurence Lyons and Robert Nick and Marc H. Weber and Ming Liu and Haig Atikian and Uwe Bauer and Alexander C. Barbati and Neil Gershenfeld},
  journal= {arXiv preprint arXiv:2604.21283},
  year   = {2026}
}
R2 v1 2026-07-01T12:31:53.054Z