Cosmological angular momentum from quantum rotation
Abstract
The origin of cosmic angular momentum is a fundamental question in structure formation. We propose a novel mechanism that generates spatial angular momentum directly from quantum fluctuations during inflation. A spectator complex scalar field with global U(1) symmetry stores internal angular momentum via field-space rotation. Inflationary perturbations create spatial gradients that, upon horizon re-entry, couple to the background charge density and source a bulk momentum flow. During nonspherical gravitational collapse, this flow converts into net angular momentum. For primordial black holes forming from such collapse, the dimensionless spin can reach when the small-scale power spectrum is enhanced to produce detectable abundances-far exceeding tidal torque theory predictions. This establishes a testable link between inflation, primordial perturbations, and black hole spin distributions accessible to gravitational-wave observations.
Cite
@article{arxiv.2603.14814,
title = {Cosmological angular momentum from quantum rotation},
author = {Bo-Qiang Lu},
journal= {arXiv preprint arXiv:2603.14814},
year = {2026}
}
Comments
6 pages, comments are welcome