Spontaneous localization at a potential saddle point from edge state reconstruction in a quantum Hall point contact

Spontaneous localization at a potential saddle point from edge state reconstruction in a quantum Hall point contact

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 loc...

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Veröffentlicht in:arXiv.org 2024-01
Hauptverfasser: Cohen, Liam A, Samuelson, Noah L, Wang, Taige, Klocke, Kai, Reeves, Cian C, Taniguchi, Takashi, Watanabe, Kenji, Sagar Vijay, Zaletel, Michael P, Young, Andrea F
Format: Artikel
Sprache:eng
Schlagworte:
Electric contacts
Graphene
Localization
Point contact
Quantum Hall effect
Reconstruction
Resonant tunneling
Saddle points
Thomas-Fermi model
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Zusammenfassung: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.
ISSN:2331-8422