Unified theory of negative and positive spectral lags in GRB prompt phase due to shear Comptonization from a structured jet

TL;DR

This paper presents a unified model explaining both positive and negative spectral lags in GRB prompt emission as a result of shear Comptonization in structured jets, accounting for observed lag transitions and high-energy photon delays.

Contribution

It introduces a shear Comptonization model in structured GRB jets that naturally explains the occurrence of both positive and negative spectral lags and their transitions.

Findings

The model predicts a lag flip from positive to negative during the prompt phase.

Comparison with observations constrains GRB jet Lorentz factors to a few tens.

The theory accounts for late onset of high-energy photons in Fermi-LAT data.

Abstract

Positive spectral lags are commonly observed in gamma-ray burst (GRB) prompt phase where soft photons lag behind hard ones in their spectral studies. Opposite to this pattern, a fraction of GRBs show a negative spectral lag where hard photons arrive later compared to soft photons. Similarly, recent Fermi-LAT observations show a late onset of high-energy photons in most GRB observations. A fraction of GRBs show a transition from positive to negative lags. Such negative lags and the spectral lag transition have no convincing explanation. We show that a structured GRB jet with velocity shear naturally produces both positive and negative spectral lags. s gain energy from repeated scattering with shearing layers and subsequently escape from higher altitudes. Hence, these photons are delayed compared to soft photons producing a negative spectral lag. The inner jet has no shear and a positive lag appears providing a unified picture of spectral lags in GRBs. The theory predicts a flip in spectral lag from positive to negative within the evolution of the prompt phase. Comparison of the observed lags with the prediction of the theory limits the possible range of GRB jet Lorentz factors to be a few tens.