English

Non-conservative current-driven dynamics: beyond the nanoscale

Mesoscale and Nanoscale Physics 2015-10-29 v1

Abstract

Long metallic nanowires combine crucial factors for non-conservative current-driven atomic mo- tion. These systems have degenerate vibrational frequencies, clustered about a Kohn anomaly in the dispersion relation, that can couple under current to form non-equilibrium modes of motion growing exponentially in time. Such motion is made possible by non-conservative current-induced forces on atoms, and we refer to it generically as the waterwheel effect. Here the connection be- tween the waterwheel effect and the stimulated directional emission of phonons propagating along the electron flow is discussed in an intuitive manner. Non-adiabatic molecular dynamics show that waterwheel modes self-regulate by reducing the current and by populating modes nearby in fre- quency, leading to a dynamical steady state in which non-conservative forces are counter-balanced by the electronic friction. The waterwheel effect can be described by an appropriate effective non- equilibrium dynamical response matrix. We show that the current-induced parts of this matrix in metallic systems are long-ranged, especially at low bias. This non-locality is essential for the characterisation of non-conservative atomic dynamics under current beyond the nanoscale.

Keywords

Cite

@article{arxiv.1510.08433,
  title  = {Non-conservative current-driven dynamics: beyond the nanoscale},
  author = {Brian Cunningham and Tchavdar N. Todorov and Daniel Dundas},
  journal= {arXiv preprint arXiv:1510.08433},
  year   = {2015}
}

Comments

15 pages 6 figures

R2 v1 2026-06-22T11:31:25.339Z