The critical role of substrate disorder in valley splitting in Si quantum wells

Journal article (2018)

Authors

Samuel F. Neyens University of Wisconsin-Madison
Ryan H. Foote University of Wisconsin-Madison
M. G. Lagally University of Wisconsin-Madison
Mark Friesen University of Wisconsin-Madison
Susan N. Coppersmith University of Wisconsin-Madison
M. A. Eriksson University of Wisconsin-Madison
Brandur Thorgrimsson University of Wisconsin-Madison
T. J. Knapp University of Wisconsin-Madison
T. McJunkin University of Wisconsin-Madison
L.M.K. Vandersypen QN/Vandersypen Lab - AS , QCD/Vandersypen Lab - QuTech Advanced Research Centre
Payam Amin Intel Labs
Nicole K. Thomas Intel Labs
James S. Clarke Intel Labs
D. E. Savage University of Wisconsin-Madison
Research Group
QCD/Vandersypen Lab (QuTech Advanced Research Centre) (TU Delft)
Copyright: © 2018 Samuel F. Neyens, Ryan H. Foote, Brandur Thorgrimsson, T. J. Knapp, Thomas McJunkin, L.M.K. Vandersypen, Payam Amin, Nicole K. Thomas, James S. Clarke, D. E. Savage, M. G. Lagally, Mark Friesen, S. N. Coppersmith, M. A. Eriksson
DOI
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https://doi.org/10.1063/1.5033447
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Published Date

11-06-2018

Language

English

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Faculty

QuTech Advanced Research Centre

Department

Quantum Computing Division

Research Group

QCD/Vandersypen Lab

Abstract

Atomic-scale disorder at the top interface of a Si quantum well is known to suppress valley splitting. Such disorder may be inherited from the underlying substrate and relaxed buffer growth, but can also arise at the top quantum well interface due to the random SiGe alloy. Here, we perform activation energy (transport) measurements in the quantum Hall regime to determine the source of the disorder affecting the valley splitting. We consider three Si/SiGe heterostructures with nominally identical substrates but different barriers at the top of the quantum well, including two samples with pure-Ge interfaces. For all three samples, we observe a surprisingly strong and universal dependence of the valley splitting on the electron density (Ev ∼ n2.7) over the entire experimental range (Ev = 30-200 μeV). We interpret these results via tight binding theory, arguing that the underlying valley physics is determined mainly by disorder arising from the substrate and relaxed buffer growth.

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