Dispersion Relations Alone Cannot Guarantee Causality

L. Gavassino; M. Disconzi; J. Noronha

doi:10.1103/PhysRevLett.132.162301

Dispersion Relations Alone Cannot Guarantee Causality

L. Gavassino, M. Disconzi, J. Noronha

Physics

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

Abstract

We show that linear superpositions of plane waves involving a single-valued, covariantly stable dispersion relation ω(k) always propagate outside the light cone unless ω(k)=a+bk. This implies that there is no notion of causality for individual dispersion relations since no mathematical condition on the function ω(k) (such as the front velocity or the asymptotic group velocity conditions) can serve as a sufficient condition for subluminal propagation in dispersive media. Instead, causality can only emerge from a careful cancellation that occurs when one superimposes all the excitation branches of a physical model. This happens automatically in local theories of matter that are covariantly stable. Hence, we find that the need for nonhydrodynamic modes in relativistic fluid mechanics is analogous to the need for antiparticles in relativistic quantum mechanics.

Original language	English (US)
Article number	162301
Journal	Physical review letters
Volume	132
Issue number	16
Early online date	Apr 17 2024
DOIs	https://doi.org/10.1103/PhysRevLett.132.162301
State	Published - Apr 19 2024

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General Physics and Astronomy

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title = "Dispersion Relations Alone Cannot Guarantee Causality",

abstract = "We show that linear superpositions of plane waves involving a single-valued, covariantly stable dispersion relation ω(k) always propagate outside the light cone unless ω(k)=a+bk. This implies that there is no notion of causality for individual dispersion relations since no mathematical condition on the function ω(k) (such as the front velocity or the asymptotic group velocity conditions) can serve as a sufficient condition for subluminal propagation in dispersive media. Instead, causality can only emerge from a careful cancellation that occurs when one superimposes all the excitation branches of a physical model. This happens automatically in local theories of matter that are covariantly stable. Hence, we find that the need for nonhydrodynamic modes in relativistic fluid mechanics is analogous to the need for antiparticles in relativistic quantum mechanics.",

author = "L. Gavassino and M. Disconzi and J. Noronha",

note = "L.\textbackslash{}u2009G. and J.\textbackslash{}u2009N. would like to thank P. Kovtun and R. Hoult for a stimulating discussion. We also thank P. Lowdon for bringing the issue of correlators in QFT to our attention. L.\textbackslash{}u2009G. is partially supported by a Vanderbilt Seeding Success Grant. M.\textbackslash{}u2009M.\textbackslash{}u2009D. is partially supported by NSF Grant No. DMS-2107701, a Chancellor\textbackslash{}u2019s Faculty Fellowship, DOE Grant No. DE-SC0024711, and a Vanderbilt Seeding Success Grant. J.\textbackslash{}u2009N. is partially supported by the U.S. Department of Energy, Office of Science, Office for Nuclear Physics under Award No. DE-SC0023861. L.\textbackslash{}u2009G. and J.\textbackslash{}u2009N. would like to thank P. Kovtun and R. Hoult for a stimulating discussion. We also thank P. Lowdon for bringing the issue of correlators in QFT to our attention. The authors thank KITP Santa Barbara for its hospitality during \textbackslash{}u201CThe Many Faces of Relativistic Fluid Dynamics\textbackslash{}u201D Program. This research was supported in part by the National Science Foundation under Grant No. NSF PHY-1748958.",

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N2 - We show that linear superpositions of plane waves involving a single-valued, covariantly stable dispersion relation ω(k) always propagate outside the light cone unless ω(k)=a+bk. This implies that there is no notion of causality for individual dispersion relations since no mathematical condition on the function ω(k) (such as the front velocity or the asymptotic group velocity conditions) can serve as a sufficient condition for subluminal propagation in dispersive media. Instead, causality can only emerge from a careful cancellation that occurs when one superimposes all the excitation branches of a physical model. This happens automatically in local theories of matter that are covariantly stable. Hence, we find that the need for nonhydrodynamic modes in relativistic fluid mechanics is analogous to the need for antiparticles in relativistic quantum mechanics.

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Dispersion Relations Alone Cannot Guarantee Causality

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