Radiative Magnetic Reconnection in Astrophysics

Abstract

I review a new rapidly growing area of high-energy plasma astrophysics --- radiative magnetic reconnection, i.e., a reconnection regime where radiation reaction influences reconnection dynamics, energetics, and nonthermal particle acceleration. This influence be may be manifested via a number of astrophysically important radiative effects, such as radiation-reaction limits on particle acceleration, radiative cooling, radiative resistivity, braking of reconnection outflows by radiation drag, radiation pressure, viscosity, and even pair creation at highest energy densities. Self-consistent inclusion of these effects in magnetic reconnection theory and modeling calls for serious modifications to our overall theoretical approach to the problem. In addition, prompt reconnection-powered radiation often represents our only observational diagnostic tool for studying remote astrophysical systems; this underscores the importance of developing predictive modeling capabilities to connect the underlying physical conditions in a reconnecting system to observable radiative signatures. This Chapter gives an overview of recent theoretical progress in developing basic physical understanding of radiative reconnection, with a special emphasis on astrophysically important radiation mechanisms like synchrotron, curvature, and inverse-Compton. It also offers a broad review of key high-energy astrophysical applications of radiative reconnection, such as: pulsar wind nebulae and magnetospheres, accreting black-hole coronae and jets in XRBs and AGN, magnetospheres of magnetars, and Gamma-Ray Bursts. Finally, this Chapter discusses the most critical open questions and outlines the directions for future research in this exciting new frontier of plasma astrophysics.