Pulsed Gamma-Ray-Burst Afterglows

TL;DR

This paper proposes a model where pulsar emission from polarization currents explains the bipolarity and afterglows of gamma-ray bursts, linking supernova observations to neutron star activity and jet dynamics.

Contribution

It introduces a novel pulsar-based model for GRB afterglows, emphasizing polarization currents and superluminal modulation as key mechanisms.

Findings

Explains supernova bipolarity via early light curve and speckle observations.

Suggests GRB afterglows are pulsed optical/near-infrared emissions from newborn neutron stars.

Provides a unified model for long and short gamma-ray bursts.

Abstract

The bipolarity of Supernova 1987A can be understood in terms of its very early light curve as observed from the CTIO 0.4-m telescope, as well as the IUE FES, and the slightly later speckle observations of the "Mystery Spot" by two groups. These observations imply a highly directional beam of light and jet of particles, with initial collimation factors in excess of 10,000, velocities in excess of 0.95 c, as an impulsive event involving up to 0.00001 solar masses, which interacts with circumstellar material. The jet and beam coincide with the 194 degree angle of the bipolarity on the sky, and are oriented at 75 degrees to the line of sight to the Earth. By day 30 the collimation of the jet decreases, and its velocity declines to ~0.5 c. These observations and the resulting kinematic solution can be understood in terms of pulsar emission from polarization currents, induced by the periodically modulated electromagnetic field beyond the pulsar light cylinder, which are thus modulated at up to many times the speed of light. With plasma available at many times the light cylinder radius, as would be the case for a spinning neutron star formed at the center of its progenitor, pulsed emission is directed close to the rotation axis, eviscerating this progenitor, and continuing for months to years, until very little circumpulsar material remains. This model provides a candidate for the central engine of the gamma-ray burst (GRB) mechanism, both long and short, and predicts that GRB afterglows are the_pulsed_ optical/near infrared emission associated with these newly-born neutron stars.