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Critical dynamics in a real-time formulation of the functional renormalization group

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arxiv 2303.11817 v1 pith:DXXGGA62 submitted 2023-03-21 hep-ph

Critical dynamics in a real-time formulation of the functional renormalization group

classification hep-ph
keywords criticaldynamicsfunctionsreal-timeformulationfunctionalgrouploop
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We present first calculations of critical spectral functions of the relaxational Models A, B, and C in the Halperin-Hohenberg classification using a real-time formulation of the functional renormalization group (FRG). We revisit the prediction by Son and Stephanov that the linear coupling of a conserved density to the non-conserved order parameter of Model A gives rise to critical Model-B dynamics. We formulate both 1-loop and 2-loop self-consistent expansion schemes in the 1PI vertex functions as truncations of the effective average action suitable for real-time applications, and analyze in detail how the different critical dynamics are properly incorporated in the framework of the FRG on the closed-time path. We present results for the corresponding critical spectral functions, extract the dynamic critical exponents for Models A, B, and C, in two and three spatial dimensions, respectively, and compare the resulting values with recent results from the literature.

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  1. Cumulant dynamics in finite-memory diffusion

    hep-th 2026-06 unverdicted novelty 6.0

    Finite current relaxation introduces memory effects that suppress, shift, and reshape non-monotonic cumulant behavior relative to instantaneous equilibrium and Fickian diffusion, most visibly in higher-order cumulants.