High-energy emission from non-relativistic radiative shocks: application to gamma-ray novae

TL;DR

This paper models high-energy emissions from radiative shocks in novae, predicting detectable hard X-ray signals that can help constrain outflow and particle acceleration properties, and differentiating between leptonic and hadronic scenarios.

Contribution

It provides the first detailed theoretical models of hard X-ray and gamma-ray emission from radiative shocks in novae, including both leptonic and hadronic processes, accounting for rapid downstream cooling.

Findings

Hard X-ray emission is a small fraction of gamma-ray luminosity, but potentially detectable with NuSTAR.

Low X-ray to gamma-ray luminosity ratio suggests leptonic models are less likely.

Combined X-ray and gamma-ray observations can constrain nova outflow and shock properties.

Abstract

Multiwavelength radiation from relativistic particles accelerated at shocks in novae and other astrophysical sources carries a wealth of information about the outflow properties and the microphysical processes at work near the shocks. The observation of GeV gamma-rays from novae by Fermi/LAT demonstrates that the shocks in these systems can accelerate particles to energies of at least $\sim 10$ GeV. The low-energy extension of the same non-thermal particle distribution inevitably gives rise to emission extending into the X-ray band. Above $\gtrsim 10$ keV this radiation can escape the system without significant absorption/attenuation, and can potentially be detected by NuSTAR. We present theoretical models for hard X-ray and gamma-ray emission from radiative shocks in both leptonic and hadronic scenarios, accounting for the rapid evolution of the downstream properties due to the fast cooling of thermal plasma. Due to strong Coulomb cooling of the mildly relativistic electrons nominally responsible for producing hard X-ray emission, only a fraction of $10^{-4} - 10^{-3}$ of the gamma-ray luminosity is radiated in the NuSTAR band; nevertheless, this emission could be detectable simultaneous with the LAT emission in bright gamma-ray novae with a $\sim 50$ ks exposure. Our work demonstrates how combined hard X-ray and gamma-ray observations can be used to constrain properties of the nova outflow (velocity, density and mass outflow rate) and particle acceleration at the shock. A very low X-ray to gamma-ray luminosity ratio ($L_{\rm X}/L_{\gamma} \lesssim 5 \times 10^{-4}$) would disfavor leptonic models for the gamma-ray emission. Our model can also be applied to other astrophysical environments with radiative shocks, including Type IIn supernovae and colliding winds in massive star binaries.