Coulomb drag in topological wires separated by an air gap

Coulomb drag in topological wires separated by an air gap

Strong electron–electron interactions between adjacent nanoscale wires can lead to one-dimensional Coulomb drag, where current in one wire induces a voltage in the second wire via Coulomb interactions. This effect creates challenges for the development of nanoelectronic devices. Quantum spin Hall (Q...

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Bibliographic Details
Published in:Nature electronics Vol. 4; no. 8; pp. 573 - 578
Main Authors: Du, Lingjie, Zheng, Jianmin, Chou, Yang-Zhi, Zhang, Jie, Wu, Xingjun, Sullivan, Gerard, Ikhlassi, Amal, Du, Rui-Rui
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 21-06-2021
Subjects:
639/766/119/2792
639/766/119/995
639/925/927/1007
Electrical Engineering
Engineering
Online Access:Get full text
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Summary:Strong electron–electron interactions between adjacent nanoscale wires can lead to one-dimensional Coulomb drag, where current in one wire induces a voltage in the second wire via Coulomb interactions. This effect creates challenges for the development of nanoelectronic devices. Quantum spin Hall (QSH) insulators are a promising platform for the development of low-power electronic devices due to their topological protection of edge states from non-magnetic disorder. However, although Coulomb drag in QSH edges has been considered theoretically, experimental explorations of the effect remain limited. Here, we show that one-dimensional Coulomb drag can be observed between adjacent QSH edges that are separated by an air gap. The pair of one-dimensional helical edge states is created in split H-bar devices in inverted InAs/GaSb quantum wells. Near the Dirac point, negative drag signals dominate at low temperatures and exhibit a non-monotonic temperature dependence, suggesting that distinct drag mechanisms compete and cancel out at higher temperatures. The results suggest that QSH effects could be used to suppress the impact of Coulomb interactions on the performance of future nanocircuits. Measurements of one-dimensional Coulomb drag between adjacent edge states of quantum spin Hall insulators that are separated by an air gap suggest that quantum spin Hall effects could be used to suppress the impact of Coulomb interactions on the performance of future nanocircuits.
ISSN:2520-1131
2520-1131
DOI:10.1038/s41928-021-00603-y