Giant Zero Bias Anomaly due to Coherent Scattering from Frozen Phonon Disorder in Quantum Point Contacts

Y. H. Lee; S. Xiao; K. W. Kim; J. L. Reno; J. P. Bird; J. E. Han

doi:10.1103/PhysRevLett.123.056802

Giant Zero Bias Anomaly due to Coherent Scattering from Frozen Phonon Disorder in Quantum Point Contacts

Y. H. Lee
, S. Xiao
, K. W. Kim
, J. L. Reno
, J. P. Bird
, J. E. Han

SUNY Buffalo
Institute for Basic Science
Sandia National Laboratories, New Mexico

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

Abstract

We demonstrate an unusual manifestation of coherent scattering for electron waves in mesoscopic quantum point contacts, in which fast electron dynamics allows the phonon system to serve as a quasistatic source of disorder. The low-temperature conductance of these devices exhibits a giant (≫2e2/h) zero bias anomaly (ZBA), the features of which are reproduced in a nonequilibrium model for coherent scattering from the "frozen" phonon disorder. According to this model, the ZBA is understood to result from the in situ electrical manipulation of the phonon disorder, a mechanism that could open up a pathway to the on-demand control of coherent scattering in the solid state.

Original language	English
Article number	056802
Journal	Physical Review Letters
Volume	123
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevLett.123.056802
State	Published - Jul 30 2019

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abstract = "We demonstrate an unusual manifestation of coherent scattering for electron waves in mesoscopic quantum point contacts, in which fast electron dynamics allows the phonon system to serve as a quasistatic source of disorder. The low-temperature conductance of these devices exhibits a giant (≫2e2/h) zero bias anomaly (ZBA), the features of which are reproduced in a nonequilibrium model for coherent scattering from the {"}frozen{"} phonon disorder. According to this model, the ZBA is understood to result from the in situ electrical manipulation of the phonon disorder, a mechanism that could open up a pathway to the on-demand control of coherent scattering in the solid state.",

author = "Lee, \{Y. H.\} and S. Xiao and Kim, \{K. W.\} and Reno, \{J. L.\} and Bird, \{J. P.\} and Han, \{J. E.\}",

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AU - Lee, Y. H.

AU - Xiao, S.

AU - Kim, K. W.

AU - Reno, J. L.

AU - Bird, J. P.

AU - Han, J. E.

PY - 2019/7/30

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AB - We demonstrate an unusual manifestation of coherent scattering for electron waves in mesoscopic quantum point contacts, in which fast electron dynamics allows the phonon system to serve as a quasistatic source of disorder. The low-temperature conductance of these devices exhibits a giant (≫2e2/h) zero bias anomaly (ZBA), the features of which are reproduced in a nonequilibrium model for coherent scattering from the "frozen" phonon disorder. According to this model, the ZBA is understood to result from the in situ electrical manipulation of the phonon disorder, a mechanism that could open up a pathway to the on-demand control of coherent scattering in the solid state.

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JO - Physical Review Letters

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ER -

Giant Zero Bias Anomaly due to Coherent Scattering from Frozen Phonon Disorder in Quantum Point Contacts

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