Open AccessMechanical Stabilization of Nanoscale Conductors by Plasmon Oscillations
Author(s) -
Maayan Kuperman,
Linoy Nagar,
Uri Peskin
Publication year - 2020
Publication title -
nano letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 4.853
H-Index - 488
eISSN - 1530-6992
pISSN - 1530-6984
DOI - 10.1021/acs.nanolett.0c02187
Subject(s) - plasmon , quantum tunnelling , conductor , non equilibrium thermodynamics , nanoscopic scale , materials science , condensed matter physics , electrical conductor , electron , instability , charge carrier , nanotechnology , chemical physics , optoelectronics , physics , mechanics , thermodynamics , quantum mechanics , composite material
External driving of the Fermion reservoirs interacting with a nanoscale charge-conductor is shown to enhance its mechanical stability during resonant tunneling. This counterintuitive cooling effect is predicted despite the net energy flow into the device. Field-induced plasmon oscillations stir the energy distribution of charge carriers near the reservoir's chemical potentials into a nonequilibrium state with favored transport of low-energy electrons. Consequently, excess heating of mechanical degrees of freedom in the conductor is suppressed. We demonstrate and analyze this effect for a generic model of mechanical instability in nanoelectronic devices, covering a broad range of parameters. Plasmon-induced stabilization is suggested as a feasible strategy to confront a major problem of current-induced heating and breakdown of nanoscale systems operating far from equilibrium.
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