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Auteurs principaux: Meadows, Robert, Xue, Y., Allbritton, Nicholas, Zhang, G. P.
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2412.04691
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author Meadows, Robert
Xue, Y.
Allbritton, Nicholas
Zhang, G. P.
author_facet Meadows, Robert
Xue, Y.
Allbritton, Nicholas
Zhang, G. P.
contents Laser-driven electron transport across a sample has garnered enormous attentions over several decades, as it provides a much faster way to control electron dynamics. Light is an electromagnetic wave, so how and why an electron can acquire a longitudinal velocity remains unanswered. Here we show that it is the magnetic field that steers the electron to the light propagation direction. But, quantitatively, our free-electron model is still unable to reproduce the experimental velocities. Going beyond the free electron mode and assuming the system absorbs all the photon energy, the theoretical velocity matches the experimental observation. We introduce a concept of the resistive transport, where electrons deaccelerate under a constant resistance after laser excitation. This theory finally explains why the experimental distance-versus-time forms a down-concave curve, and unifies ballistic and superdiffusive transports into a single resistive transport. We expect that our finding will motivate further investigations.
format Preprint
id arxiv_https___arxiv_org_abs_2412_04691
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A simple model for longitudinal electron transport during and after laser excitation: Emergence of electron resistive transport
Meadows, Robert
Xue, Y.
Allbritton, Nicholas
Zhang, G. P.
Materials Science
Computational Physics
Optics
Quantum Physics
Laser-driven electron transport across a sample has garnered enormous attentions over several decades, as it provides a much faster way to control electron dynamics. Light is an electromagnetic wave, so how and why an electron can acquire a longitudinal velocity remains unanswered. Here we show that it is the magnetic field that steers the electron to the light propagation direction. But, quantitatively, our free-electron model is still unable to reproduce the experimental velocities. Going beyond the free electron mode and assuming the system absorbs all the photon energy, the theoretical velocity matches the experimental observation. We introduce a concept of the resistive transport, where electrons deaccelerate under a constant resistance after laser excitation. This theory finally explains why the experimental distance-versus-time forms a down-concave curve, and unifies ballistic and superdiffusive transports into a single resistive transport. We expect that our finding will motivate further investigations.
title A simple model for longitudinal electron transport during and after laser excitation: Emergence of electron resistive transport
topic Materials Science
Computational Physics
Optics
Quantum Physics
url https://arxiv.org/abs/2412.04691