Giant g-factors and fully spin-polarized states in metamorphic short-period InAsSb/InSb superlattices

Yuxuan Jiang; Maksim Ermolaev; Gela Kipshidze; Seongphill Moon; Mykhaylo Ozerov; Dmitry Smirnov; Zhigang Jiang; Sergey Suchalkin

doi:10.1038/s41467-022-33560-x

Giant g-factors and fully spin-polarized states in metamorphic short-period InAsSb/InSb superlattices

Yuxuan Jiang
, Maksim Ermolaev
, Gela Kipshidze
, Seongphill Moon
, Mykhaylo Ozerov
, Dmitry Smirnov
, Zhigang Jiang
, Sergey Suchalkin

Stony Brook University

Georgia Institute of Technology
National High Magnetic Field Laboratory
Stony Brook University
Florida State University

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

Realizing a large Landé g-factor of electrons in solid-state materials has long been thought of as a rewarding task as it can trigger abundant immediate applications in spintronics and quantum computing. Here, by using metamorphic InAsSb/InSb superlattices (SLs), we demonstrate an unprecedented high value of g ≈ 104, twice larger than that in bulk InSb, and fully spin-polarized states at low magnetic fields. In addition, we show that the g-factor can be tuned on demand from 20 to 110 via varying the SL period. The key ingredients of such a wide tunability are the wavefunction mixing and overlap between the electron and hole states, which have drawn little attention in prior studies. Our work not only establishes metamorphic InAsSb/InSb as a promising and competitive material platform for future quantum devices but also provides a new route toward g-factor engineering in semiconductor structures.

Original language	English
Article number	5960
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-33560-x
State	Published - Dec 2022

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abstract = "Realizing a large Land{\'e} g-factor of electrons in solid-state materials has long been thought of as a rewarding task as it can trigger abundant immediate applications in spintronics and quantum computing. Here, by using metamorphic InAsSb/InSb superlattices (SLs), we demonstrate an unprecedented high value of g ≈ 104, twice larger than that in bulk InSb, and fully spin-polarized states at low magnetic fields. In addition, we show that the g-factor can be tuned on demand from 20 to 110 via varying the SL period. The key ingredients of such a wide tunability are the wavefunction mixing and overlap between the electron and hole states, which have drawn little attention in prior studies. Our work not only establishes metamorphic InAsSb/InSb as a promising and competitive material platform for future quantum devices but also provides a new route toward g-factor engineering in semiconductor structures.",

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AU - Jiang, Yuxuan

AU - Ermolaev, Maksim

AU - Kipshidze, Gela

AU - Moon, Seongphill

AU - Ozerov, Mykhaylo

AU - Smirnov, Dmitry

AU - Jiang, Zhigang

AU - Suchalkin, Sergey

PY - 2022/12

Y1 - 2022/12

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AB - Realizing a large Landé g-factor of electrons in solid-state materials has long been thought of as a rewarding task as it can trigger abundant immediate applications in spintronics and quantum computing. Here, by using metamorphic InAsSb/InSb superlattices (SLs), we demonstrate an unprecedented high value of g ≈ 104, twice larger than that in bulk InSb, and fully spin-polarized states at low magnetic fields. In addition, we show that the g-factor can be tuned on demand from 20 to 110 via varying the SL period. The key ingredients of such a wide tunability are the wavefunction mixing and overlap between the electron and hole states, which have drawn little attention in prior studies. Our work not only establishes metamorphic InAsSb/InSb as a promising and competitive material platform for future quantum devices but also provides a new route toward g-factor engineering in semiconductor structures.

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Giant g-factors and fully spin-polarized states in metamorphic short-period InAsSb/InSb superlattices

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