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Main Authors: Alkhateeb, M., de la Cal, X. Gutierrez, Pons, M., Sokolovski, D., Matzkin, A.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.07160
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author Alkhateeb, M.
de la Cal, X. Gutierrez
Pons, M.
Sokolovski, D.
Matzkin, A.
author_facet Alkhateeb, M.
de la Cal, X. Gutierrez
Pons, M.
Sokolovski, D.
Matzkin, A.
contents We investigate relativistic wavepacket dynamics for an electron tunneling through a potential barrier employing space-time resolved solutions to relativistic quantum field theory (QFT) equations. We prove by linking the QFT property of micro-causality to the wavepacket behavior that the tunneling dynamics is fully causal, precluding instantaneous or superluminal effects that have recently been reported in the literature. We illustrate these results by performing numerical computations for an electron tunneling through a potential barrier for standard tunneling as well for Klein tunneling. In all cases (Klein tunneling \ or regular tunneling across a standard or a supercritical potential) the transmitted wavepacket remains in the causal envelope of the propagator, even when its average position lies ahead of the average position of the corresponding freely propagated wavepacket.
format Preprint
id arxiv_https___arxiv_org_abs_2407_07160
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Relativistic Quantum Field Theory Approach to Wavepacket Tunneling: Lack of Superluminal Transmission
Alkhateeb, M.
de la Cal, X. Gutierrez
Pons, M.
Sokolovski, D.
Matzkin, A.
Quantum Physics
High Energy Physics - Theory
We investigate relativistic wavepacket dynamics for an electron tunneling through a potential barrier employing space-time resolved solutions to relativistic quantum field theory (QFT) equations. We prove by linking the QFT property of micro-causality to the wavepacket behavior that the tunneling dynamics is fully causal, precluding instantaneous or superluminal effects that have recently been reported in the literature. We illustrate these results by performing numerical computations for an electron tunneling through a potential barrier for standard tunneling as well for Klein tunneling. In all cases (Klein tunneling \ or regular tunneling across a standard or a supercritical potential) the transmitted wavepacket remains in the causal envelope of the propagator, even when its average position lies ahead of the average position of the corresponding freely propagated wavepacket.
title Relativistic Quantum Field Theory Approach to Wavepacket Tunneling: Lack of Superluminal Transmission
topic Quantum Physics
High Energy Physics - Theory
url https://arxiv.org/abs/2407.07160