From Empirical to Physical Model: Direct Fits of Optically Thin Inverse Compton Scattering to Prompt GRB Spectra

Abstract

Gamma-ray burst (GRB) prompt emission is commonly attributed to non-thermal radiation processes operating in the optically thin regions of a relativistic outflow. Among these, optically thin inverse-Compton (IC) scattering remains an important yet under-tested mechanism. From an initial set of 41 bursts selected using empirical Band-function criteria that highlight quasi-thermal low-energy slopes (α > -0.5) and constrained high-energy indices (-1.7 > β > -3.3), only four events satisfy these conditions consistently in both time-integrated and time-resolved spectra. The IC fits yield self-consistent constraints on the seed-photon field and the electron population at the dissipation site. For bulk Lorentz factors 170-550, we infer seed thermal peaks of 0.05-0.2 keV and electron thermal energies of 20-300 keV in the co-moving frame. A fraction of only 0.1\%-20\% of electrons are accelerated into a non-thermal tail with an average index value of δ 1.8. The derived Comptonisation parameters indicate moderate y values ( 1-3), optical depths τ 0.2-0.6, and dissipation radii just above the photosphere, consistent with mildly relativistic (γ 1.2-2.6), photon-dominated, low-magnetic-field dissipation environments. Furthermore, the framework allows us to constrain even sub-dominant thermal components that lie below the detector's low-energy threshold. Taken together, our results show that optically thin IC scattering offers a physically consistent and observationally viable explanation for the prompt emission in a subset of bright GRBs, motivating the application of IC models in future GRB studies.

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