Using BATSE Observations to Test the Compton Attenuation Spectral Theory of Cosmological Gamma‐Ray Bursts

Abstract

The Compton attenuation theory provides an explanation for the characteristic spectral energy possessed by gamma-ray bursts. It makes several predictions that can be tested with current data, two of which are the characteristic shape of the spectrum and the presence of an X-ray excess. We have performed these tests by fitting the Compton attenuation spectral model to 25 gamma-ray bursts from the BATSE 3B catalog. Minimizing χ² with four free parameters, we find values of χ² with the same level of significance as the values found for the best-fitting four-parameter models of previous studies. The X-ray upturn makes the χ² for the Compton attenuation spectrum smaller than for a comparison spectrum that is a power law over the X-ray energy band. The values of the free parameters derived from the model fits are physically meaningful, and each describes the spectrum over a different frequency band. The absence of a correlation between z and the energy in the comoving frame of the peak of the νF_ν curve provides support for the model's physical validity. A model fit to a gamma-ray burst's spectrum between 5 and 100 keV gives the redshift of the source; we typically find values of z between 1 and 5. The spread in z are consistent with the spread of redshifts for a broad luminosity function, but the large values require source evolution. Additional tests of the theory are available with current experiments and will be possible with several planned and proposed experiments.