Universal spectrum and scaling laws for halo mass function, structure, and dark matter mass constraints

Abstract

Between the linear and nonlinear regimes, we identify a universal transition range centered on a characteristic halo mass mh* t, within which gravitational dynamics self-organize the matter field toward an effective spectral index n=-1. In a bottom-up hierarchy, early collapse of low-mass halos preserves imprints of the primordial spectrum, whereas prolonged assembly of halos near mh* erases that memory and establishes universality. We formulate a scale-to-scale cascade, the redistribution of mass and energy across scales, that yields universal scaling laws for the halo mass function and internal structure. Globally, the cascade drives a random walk of halos with mass-dependent waiting time τg mh-λ; A Fokker-Planck equation gives mass function fM mh-λ and λ=2/3 for the gravity-dominant transition range. Locally, a radially directed cascade governs particle migration with waiting time τgr r-γ, yielding density r r-2γ and γ=2/3 on scales near mh*. The cascade drives the system toward a statistically steady state that continuously releases energy and maximizes entropy, characterized by scale-independent rates, preventing mass or energy buildup at intermediate scales. Scale-dependent dominance of the primordial spectrum versus gravity implies two effective exponents, producing double-λ mass functions and double-γ density in excellent agreement with simulations. Using Illustris and Virgo, we measure an inverse kinetic-energy cascade from small to large scales at u ≈ -10-7m2/s3, a direct potential-energy cascade of -1.4u, and a net dissipation of -0.4u via halo mergers and particle migration. The dependence of waiting time and step length on the particle mass suggests new constraints near 1012GeV.