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Lorentz-boosted diffusion: initial value formulation and exact solutions

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arxiv 2602.21254 v2 pith:DC7LFVFF submitted 2026-02-23 math-ph gr-qchep-thmath.MPnucl-th

Lorentz-boosted diffusion: initial value formulation and exact solutions

classification math-ph gr-qchep-thmath.MPnucl-th
keywords diffusionboostedequationexactformfunctiongreeninitial
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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It is well known that the diffusion equation, when treated as a stand-alone partial differential equation, exhibits exponential instabilities in boosted frames, which render the corresponding initial-value problem ill-posed. Recently, however, it was shown that Fick-type diffusion arises as the exact hydrodynamic sector of relativistic Fokker-Planck kinetic theory. In this work, we exploit this kinetic embedding to formulate a modified initial-value problem for one-dimensional Lorentz-boosted diffusion. We show that the resulting dynamics are well posed both forward and backward in time, provided the boosted density profiles admit a kinetic-theory realization. Such profiles form a space of band-limited functions, within which the evolution can be expressed as a discrete superposition of spatially sampled initial data, weighted by a Shannon-Whittaker-type Green function defined on the full Minkowski plane. The Green function is obtained in closed analytic form.

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