Zero-Field Dissipationless Chiral Edge Transport and the Nature of Dissipation in the Quantum Anomalous Hall State

Cui Zu Chang; Weiwei Zhao; Duk Y. Kim; Peng Wei; J. K. Jain; Chaoxing Liu; Moses H.W. Chan; Jagadeesh S. Moodera

doi:10.1103/PhysRevLett.115.057206

Zero-Field Dissipationless Chiral Edge Transport and the Nature of Dissipation in the Quantum Anomalous Hall State

Cui Zu Chang, Weiwei Zhao, Duk Y. Kim, Peng Wei, J. K. Jain, Chaoxing Liu, Moses H.W. Chan, Jagadeesh S. Moodera

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

130 Scopus citations

Abstract

The quantum anomalous Hall (QAH) effect is predicted to possess, at a zero magnetic field, chiral edge channels that conduct a spin polarized current without dissipation. While edge channels have been observed in previous experimental studies of the QAH effect, their dissipationless nature at a zero magnetic field has not been convincingly demonstrated. By a comprehensive experimental study of the gate and temperature dependences of local and nonlocal magnetoresistance, we unambiguously establish the dissipationless edge transport. By studying the onset of dissipation, we also identify the origin of dissipative channels and clarify the surprising observation that the critical temperature of the QAH effect is 2 orders of magnitude smaller than the Curie temperature of ferromagnetism.

Original language	English (US)
Article number	057206
Journal	Physical review letters
Volume	115
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevLett.115.057206
State	Published - Jul 31 2015

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.115.057206

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title = "Zero-Field Dissipationless Chiral Edge Transport and the Nature of Dissipation in the Quantum Anomalous Hall State",

abstract = "The quantum anomalous Hall (QAH) effect is predicted to possess, at a zero magnetic field, chiral edge channels that conduct a spin polarized current without dissipation. While edge channels have been observed in previous experimental studies of the QAH effect, their dissipationless nature at a zero magnetic field has not been convincingly demonstrated. By a comprehensive experimental study of the gate and temperature dependences of local and nonlocal magnetoresistance, we unambiguously establish the dissipationless edge transport. By studying the onset of dissipation, we also identify the origin of dissipative channels and clarify the surprising observation that the critical temperature of the QAH effect is 2 orders of magnitude smaller than the Curie temperature of ferromagnetism.",

author = "Chang, {Cui Zu} and Weiwei Zhao and Kim, {Duk Y.} and Peng Wei and Jain, {J. K.} and Chaoxing Liu and Chan, {Moses H.W.} and Moodera, {Jagadeesh S.}",

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AU - Chang, Cui Zu

AU - Zhao, Weiwei

AU - Kim, Duk Y.

AU - Wei, Peng

AU - Jain, J. K.

AU - Liu, Chaoxing

AU - Chan, Moses H.W.

AU - Moodera, Jagadeesh S.

PY - 2015/7/31

Y1 - 2015/7/31

N2 - The quantum anomalous Hall (QAH) effect is predicted to possess, at a zero magnetic field, chiral edge channels that conduct a spin polarized current without dissipation. While edge channels have been observed in previous experimental studies of the QAH effect, their dissipationless nature at a zero magnetic field has not been convincingly demonstrated. By a comprehensive experimental study of the gate and temperature dependences of local and nonlocal magnetoresistance, we unambiguously establish the dissipationless edge transport. By studying the onset of dissipation, we also identify the origin of dissipative channels and clarify the surprising observation that the critical temperature of the QAH effect is 2 orders of magnitude smaller than the Curie temperature of ferromagnetism.

AB - The quantum anomalous Hall (QAH) effect is predicted to possess, at a zero magnetic field, chiral edge channels that conduct a spin polarized current without dissipation. While edge channels have been observed in previous experimental studies of the QAH effect, their dissipationless nature at a zero magnetic field has not been convincingly demonstrated. By a comprehensive experimental study of the gate and temperature dependences of local and nonlocal magnetoresistance, we unambiguously establish the dissipationless edge transport. By studying the onset of dissipation, we also identify the origin of dissipative channels and clarify the surprising observation that the critical temperature of the QAH effect is 2 orders of magnitude smaller than the Curie temperature of ferromagnetism.

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Zero-Field Dissipationless Chiral Edge Transport and the Nature of Dissipation in the Quantum Anomalous Hall State

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