Wave-Tide Locking in Thin Stellar Streams: A Phenomenological Mass Spectrometer for an Intermediate Ultralight Axion

Abstract

We propose a phenomenological mass estimator for an intermediate ultralight axion dark-matter component using thin stellar streams. The central observation is an analytic relation linking three length scales in a fuzzy-dark-matter stream progenitor: the tidal radius of a bound dark core, its gravitational Bohr radius, and the axion de Broglie wavelength evaluated at the stripped-star velocity scale. If the stream width is (w=Cw r t), with (Cw=O(1)), then [ r tr B =========================== 4π2Cw2 (wλ dB)2 . ] Thus (λ dB w) automatically implies (r t/r B25)--(40): the dark wave core survives well inside the tidal boundary while the extended stellar envelope is stripped into a thin stream. This wave--tide locking gives a no-simulation axion-mass estimator, [ ma 2.69×10-19, eV (2qκ) (R10, kpc) (38, pcw)2 (w ripple) (220, km,s-1vc). ] In the simplest locked case ( ripple w), a homogeneous first-pass set of narrow stream widths points to (ma) of a few (10-19, eV) and hidden-core masses of a few (103)--(104M). This is not a detection claim; it is a falsifiable phenomenological test for an ultralight axion component that can be sharpened by homogeneous stream catalogs and Schrödinger--Poisson simulations.