English

Laughlin pumping assisted by surface acoustic waves

Mesoscale and Nanoscale Physics 2026-01-21 v1

Abstract

The quantum Hall effect is a fascinating electrical transport phenomenon signified by precise quantization of Hall conductivity σxy\sigma_\mathrm{xy} and vanishing longitudinal conductivity σxx\sigma_\mathrm{xx}. Laughlin proposed an elegant explanation in which adiabatic insertion of a flux tube pumps charge through the system. This analysis unveils the fundamental role of gauge invariance and provides a compelling argument about the fractional charge of fractional quantum Hall states. While it has been used extensively as a theoretical tool, a quantitative experimental investigation is lacking despite multiple attempts. Here we report successful realizations of Laughlin pumping in several integer and fractional quantum Hall states. One essential technical innovation is using surface acoustic waves to periodically clear the charges accumulated during the pumping process. Magnetic fluxes are inserted at a constant rate so there is no need to perform complicated data fitting. Furthermore, our setting can reliably extract σxx\sigma_\mathrm{xx} that is several orders of magnitude lower than the limit of conventional techniques. Effective energy gaps can be deduced from the temperature dependence of σxx\sigma_\mathrm{xx}, which are drastically different from those provided by conventional transport data. This work not only brings a famous gedanken experiment to reality but also serves as a portal for many future investigations.

Keywords

Cite

@article{arxiv.2601.11921,
  title  = {Laughlin pumping assisted by surface acoustic waves},
  author = {Renfei Wang and Xiao Liu and Adbhut Gupta and Kirk W. Baldwin and Loren Pfeiffer and Wenfeng Zhang and Rui-Rui Du and Mansour Shayegan and Xi Lin and Ying-Hai Wu and Yang Liu},
  journal= {arXiv preprint arXiv:2601.11921},
  year   = {2026}
}

Comments

23 pages, 14 figures

R2 v1 2026-07-01T09:08:41.452Z