High energy modifications of blackbody radiation and dimensional reduction

Viqar Husain, Sanjeev S. Seahra, and Eric J. Webster

Phys. Rev. D 88, 024014 – Published 9 July 2013

Abstract

Quantization prescriptions that realize generalized uncertainty relations are motivated by quantum gravity arguments that incorporate a fundamental length scale. We apply two such methods, polymer and deformed Heisenberg quantization, to scalar field theory in Fourier space. These alternative quantizations modify the oscillator spectrum for each mode, which in turn affects the blackbody distribution. We find that for a large class of modifications, the equation of state relating pressure $P$ and energy density $ρ$ interpolates between $P = ρ / 3$ at low $T$ and $P = 2 ρ / 3$ at high $T$ , where $T$ is the temperature. Furthermore, the Stefan-Boltzman law gets modified from $ρ \propto T^{4}$ to $ρ \propto T^{5 / 2}$ at high temperature. This suggests an effective reduction to 2.5 spacetime dimensions at high energy.

Received 3 June 2013

DOI:https://doi.org/10.1103/PhysRevD.88.024014

Authors & Affiliations

Viqar Husain^1,*, Sanjeev S. Seahra^1,†, and Eric J. Webster^2,‡

¹Department of Mathematics and Statistics, University of New Brunswick, Fredericton, New Brunswick E3B 5A3, Canada
²Department of Applied Mathematics, University of Waterloo, Waterloo, Ontario N2L 3G1, Canada

^*husain@unb.ca
^†sseahra@unb.ca
^‡ewebster@uwaterloo.ca

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Vol. 88, Iss. 2 — 15 July 2013

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Physical Review D

covering particles, fields, gravitation, and cosmology