Emergent Local Phase-Space Scaling in Small-x Gluon Evolution
Abstract
Geometric scaling is a central output of nonlinear small-x evolution, but it is less clear whether the same dynamics fixes a probability distribution in transverse phase space. Using fixed-coupling impact-parameter BK evolution in the SO(3)-symmetric construction, we build a normalized gluon Husimi phase-space distribution and resolve it with a local coarse graining whose ultraviolet boundary follows Qs(Y,b). The main result is a distribution-level one: after this Qs-adaptive resolution, the conditional momentum distributions collapse as functions of k/Qs(Y,b). The conditional entropy then grows with unit slope relative to Qs2, as the integrated consequence of that collapse and the two-dimensional momentum measure. Fixed laboratory cutoffs do not show this law, while dense-rapidity, cutoff-window, box-size, regulator-shape, and Husimi-resolution scans keep the Qs-adaptive result stable in the controlled window. Within this fixed-coupling SO(3)-BK setting, the result identifies a local phase-space scaling structure of the gluon Husimi distribution rather than a universal law for unregulated global entropy.
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