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Bibliographic Details
Main Authors: Palastro, J. P., Ramsey, D., Formanek, M., Vieira, J., Di Piazza, A.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.00209
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author Palastro, J. P.
Ramsey, D.
Formanek, M.
Vieira, J.
Di Piazza, A.
author_facet Palastro, J. P.
Ramsey, D.
Formanek, M.
Vieira, J.
Di Piazza, A.
contents The Dirac equation has resided among the greatest successes of modern physics since its emergence as the first quantum mechanical theory fully compatible with special relativity. This compatibility ensures that the expectation value of the velocity is less than the vacuum speed of light. Here, we show that the Dirac equation admits free-particle solutions where the peak amplitude of the wavefunction can travel at any velocity, including those exceeding the vacuum speed of light, despite having a subluminal velocity expectation value. The solutions are constructed by superposing basis functions with correlations in momentum space. These arbitrary velocity wavefunctions feature a near-constant profile and may impact quantum mechanical processes that are sensitive to the local value of the probability density as opposed to expectation values.
format Preprint
id arxiv_https___arxiv_org_abs_2405_00209
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Superluminal matter waves
Palastro, J. P.
Ramsey, D.
Formanek, M.
Vieira, J.
Di Piazza, A.
Quantum Physics
High Energy Physics - Phenomenology
The Dirac equation has resided among the greatest successes of modern physics since its emergence as the first quantum mechanical theory fully compatible with special relativity. This compatibility ensures that the expectation value of the velocity is less than the vacuum speed of light. Here, we show that the Dirac equation admits free-particle solutions where the peak amplitude of the wavefunction can travel at any velocity, including those exceeding the vacuum speed of light, despite having a subluminal velocity expectation value. The solutions are constructed by superposing basis functions with correlations in momentum space. These arbitrary velocity wavefunctions feature a near-constant profile and may impact quantum mechanical processes that are sensitive to the local value of the probability density as opposed to expectation values.
title Superluminal matter waves
topic Quantum Physics
High Energy Physics - Phenomenology
url https://arxiv.org/abs/2405.00209