Effect of Quantum Hall Edge Strips on Valley Splitting in Silicon Quantum Wells

Journal article (2020)

Authors

B. Paquelet Wuetz Kavli institute of nanoscience Delft, QCD/Scappucci Lab - QuTech Advanced Research Centre , QuTech Advanced Research Centre
Merritt P. Losert University of Wisconsin-Madison
A. Tosato QuTech Advanced Research Centre, QCD/Scappucci Lab - QuTech Advanced Research Centre , Kavli institute of nanoscience Delft
M. Lodari QCD/Scappucci Lab - QuTech Advanced Research Centre , QuTech Advanced Research Centre, Kavli institute of nanoscience Delft
P.L. Bavdaz Kavli institute of nanoscience Delft, QuTech Advanced Research Centre, QCD/Scappucci Lab - QuTech Advanced Research Centre
Lucas Stehouwer Student, Kavli institute of nanoscience Delft
A. Sammak TNO, Business Development
M. Veldhorst QuTech Advanced Research Centre, Kavli institute of nanoscience Delft, QCD/Veldhorst Lab - QuTech Advanced Research Centre
G. Scappucci Kavli institute of nanoscience Delft, QuTech Advanced Research Centre, QCD/Scappucci Lab - QuTech Advanced Research Centre
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Research Group
QCD/Scappucci Lab (QuTech Advanced Research Centre) (TU Delft)
Copyright: © 2020 B. Paquelet Wuetz, Merritt P. Losert, A. Tosato, M. Lodari, P.L. Bavdaz, Lucas Stehouwer, A. Sammak, M. Veldhorst, G. Scappucci, More Authors
DOI: https://doi.org/10.1103/PhysRevLett.125.186801
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Published Date

2020

Language

English

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Faculty

QuTech Advanced Research Centre

Department

Quantum Computing Division

Research Group

QCD/Scappucci Lab

Abstract

We determine the energy splitting of the conduction-band valleys in two-dimensional electrons confined to low-disorder Si quantum wells. We probe the valley splitting dependence on both perpendicular magnetic field B and Hall density by performing activation energy measurements in the quantum Hall regime over a large range of filling factors. The mobility gap of the valley-split levels increases linearly with B and is strikingly independent of Hall density. The data are consistent with a transport model in which valley splitting depends on the incremental changes in density eB/h across quantum Hall edge strips, rather than the bulk density. Based on these results, we estimate that the valley splitting increases with density at a rate of 116 μeV/1011 cm-2, which is consistent with theoretical predictions for near-perfect quantum well top interfaces.