Power-Law Approach of the Stress-Energy Tensor to the Unruh State after Gravitational Collapse

Abstract

We establish the rate at which the renormalized stress--energy tensor of a massless minimally coupled scalar field in the in-vacuum state of a collapsing null-shell spacetime approaches the corresponding Unruh-state value. At finite exterior radius, we establish the upper bound \[ | Tμ|≤ C(r)\,ts-3 \] from the Cauchy-surface decomposition of the Hadamard difference and the branch-cut structure of the retarded Green function. At future null infinity, we show that the leading coefficient in the late-time expansion \[ Tuu Cuu\,us-3 \] is nonzero, by computing the branch-cut residue explicitly at small frequency and using the Planck suppression of the thermal spectrum at large frequency to show that the dominant contribution to Cuu has a definite sign. The result gives \[ Tuu|+(us) Cuu\,us-3, us∞, \] with Cuu≠ 0. The exponent is determined by the ω2ω branch-point singularity in the Wronskian of the =0 radial wave equation, the same structure responsible for Price's law. The sign Cuu<0 is supported by a physical argument and by the numerical mode data of Gholizadeh Siahmazgi, Anderson, and Fabbri. The result confirms their conjecture that the approach is a power law. We conjecture that the same mechanism gives an analogous ts-7 bound for gravitational perturbations (=2), though the extension to the spin-2 case involves gauge issues not addressed here.