Spontaneous localization at a potential saddle point from edge state reconstruction in a quantum Hall point contact — Liam A. Cohen (2024) | RDL Network
Spontaneous localization at a potential saddle point from edge state reconstruction in a quantum Hall point contact
Preprint 2024 en
Authors
LC
Liam A. Cohen
NS
Noah L. Samuelson
TW
Taige Wang
Abstract
1 min read
Quantum point contacts (QPCs) are an essential component in mesoscopic devices. Here, we study the transmission of quantum Hall edge modes through a gate-defined QPC in monolayer graphene. We observe resonant tunneling peaks and a nonlinear conductance pattern characteristic of Coulomb-blockaded localized states. The in-plane electric polarizability reveals the states are localized at a classically-unstable electrostatic saddle point. We explain this unexpected finding within a self-consistent Thomas-Fermi model, finding that localization of a zero-dimensional state at the saddle point is favored whenever the applied confinement potential is sufficiently soft compared to the Coulomb energy. Our results provide a direct demonstration of Coulomb-driven reconstruction at the boundary of a quantum Hall system.
Liam Cohen, Noah L. Samuelson, Taige Wang, Kai Klocke, Cian C. Reeves, Takashi Taniguchi, Kenji Watanabe, Sagar Vijay, Michael P. Zaletel, Andrea F. Young
M.O. Garg, Olivier Maillet, Noah L. Samuelson, Tianle Wang, Juanjuan Feng, Liam Cohen, Aifei Zhang, Kenji Watanabe, Takashi Taniguchi, P. Roulleau, Maura Sassetti, Michael P. Zaletel, Andrea F. Young, Dario Ferraro, P. Roche, François Parmentier
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