Operational measurement of relativistic equilibrium from stochastic fields alone

Abstract

The inverse-temperature four-vector βμ= uμ/(kB T0) has been the theoretically accepted description of relativistic equilibrium since van Kampen and Israel, yet no experiment has ever reconstructed βμ as a single observable. All existing methods -- Thomson scattering, spectral fitting, blast-wave models -- infer rest-frame temperature and flow velocity from separate measurements. We propose the first protocol that extracts both components of βμ from the same passive observable: electromagnetic fluctuation correlations emitted by a drifting medium. A dimensionless E-B cross-spectral ratio yields the drift velocity from Lorentz mixing of the field-strength tensor, while angle-resolved noise power governed by the covariant fluctuation-dissipation theorem provides the rest-frame temperature via a ratio method that cancels absolute amplitude. Together, these reconstruct βμ without external probes, spectral lines, or absolute radiometric calibration. The protocol enables the first direct experimental test of whether the thermal state of a relativistic medium transforms as a four-vector -- a question unresolved since the Planck--Ott-Landsberg controversy of 1907. Monte Carlo simulations parameterized to the HIGGINS dual 100\,TW laser-plasma facility demonstrate sub-percent temperature recovery for γ= 1.05-10, with robustness to additive noise at SNR~ 10.