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Main Author: Gavassino, Lorenzo
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.07031
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author Gavassino, Lorenzo
author_facet Gavassino, Lorenzo
contents We construct a causal and covariantly stable kinetic model whose spectrum at real wavenumbers $k$ reproduces any rest-frame stable dissipative dispersion relation $ω(k)$ via suitable initialization of the microscopic degrees of freedom. Macroscopic observables can therefore obey arbitrary linear evolution equations (including forms that would be acausal if taken as fundamental), while the underlying dynamics remains causal, and all apparent propagation is encoded in the initial data. This provides an explicit counterexample to the idea that microscopic causality alone constrains the analytic form of dispersion relations at real $k$. In particular, bounds on transport coefficients based solely on the analytic structure of $ω(k)$, such as the hydrohedron bounds, require additional assumptions about the region in the complex $k$-plane where $ω(k)$ corresponds to physical modes.
format Preprint
id arxiv_https___arxiv_org_abs_2604_07031
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle How acausal equations emerge from causal dynamics
Gavassino, Lorenzo
Nuclear Theory
High Energy Physics - Theory
Mathematical Physics
We construct a causal and covariantly stable kinetic model whose spectrum at real wavenumbers $k$ reproduces any rest-frame stable dissipative dispersion relation $ω(k)$ via suitable initialization of the microscopic degrees of freedom. Macroscopic observables can therefore obey arbitrary linear evolution equations (including forms that would be acausal if taken as fundamental), while the underlying dynamics remains causal, and all apparent propagation is encoded in the initial data. This provides an explicit counterexample to the idea that microscopic causality alone constrains the analytic form of dispersion relations at real $k$. In particular, bounds on transport coefficients based solely on the analytic structure of $ω(k)$, such as the hydrohedron bounds, require additional assumptions about the region in the complex $k$-plane where $ω(k)$ corresponds to physical modes.
title How acausal equations emerge from causal dynamics
topic Nuclear Theory
High Energy Physics - Theory
Mathematical Physics
url https://arxiv.org/abs/2604.07031