Mesoscopic Klein-Schwinger effect in graphene
Abstract
Strong electric field annihilation by particle-antiparticle pair creation, also known as the Schwinger effect, is a non-perturbative prediction of quantum electrodynamics. Its experimental demonstration remains elusive, as threshold electric fields are extremely strong and beyond current reach. Here, we propose a mesoscopic variant of the Schwinger effect in graphene, which hosts Dirac fermions with an approximate electron-hole symmetry. Using transport measurements, we report on universal 1d-Schwinger conductance at the pinchoff of ballistic graphene transistors. Strong pinchoff electric fields are concentrated within approximately 1 m of the transistor's drain, and induce Schwinger electron-hole pair creation at saturation. This effect precedes a collective instability toward an ohmic Zener regime, which is rejected at twice the pinchoff voltage in long devices. These observations advance our understanding of current saturation limits in ballistic graphene and provide a direction for further quantum electrodynamic experiments in the laboratory.
Cite
@article{arxiv.2207.13400,
title = {Mesoscopic Klein-Schwinger effect in graphene},
author = {A. Schmitt and P. Vallet and D. Mele and M. Rosticher and T. Taniguchi and K. Watanabe and E. Bocquillon and G. Fève and J. M. Berroir and C. Voisin and J. Cayssol and M. O. Goerbig and J. Troost and E. Baudin and B. Plaçais},
journal= {arXiv preprint arXiv:2207.13400},
year = {2023}
}
Comments
39 pages, 13 figures, final version with extended discussion of the pinchoff effect in supplementary informations, abstract updated