Fast-Cooling Synchrotron in Decaying Magnetic Fields: Implications for the GRB Spectral Distribution

Abstract

The prompt-emission spectra of gamma-ray bursts (GRBs) are commonly described by the empirical Band function. The typical low-energy spectral index is -1, which poses a challenge to standard synchrotron radiation models. We systematically investigate a fast-cooling synchrotron model with a decaying magnetic field and test, within an observation-consistent pipeline, whether it reproduces the Band-fit parameter distributions in the GBM catalog, in a statistical sense. We solve the electron continuity equation with synchrotron, adiabatic, and synchrotron self-Compton cooling to obtain the time-dependent electron distribution and synthetic spectra; we then forward-fold through the GBM response matrices and recover (α, β, Ep) with Band fits. We find that magnetic-field decay can harden the recovered α relative to the fast-cooling limit in part of parameter space, but the effect is not robust and is sensitive to the location of Ep within the finite band and to spectral curvature; varying key physical scales reshapes the recovered α distribution, indicating that catalog α often represents an effective in-band slope rather than the asymptotic index. SSC cooling provides modest additional hardening and, in our setups, does not stabilize α near the observed peak. Using Monte Carlo samples designed to mimic the observations, the model yields α mostly between -1.5 and -0.8, but remains centered around α ≈ -1.5. Overall, while decaying-field fast-cooling synchrotron can partially alleviate overly soft spectra expected from standard fast-cooling synchrotron emission, it still falls short of reproducing the GBM α distribution at the population level, implying that additional physical processes are required.