On the nature of the energy-dependent morphology of the composite multi-TeV gamma-ray source HESS J1702-420

TL;DR

This paper models the energy-dependent morphology of the gamma-ray source HESS J1702-420 as a result of proton propagation effects from a central accelerator within a dense cloud, explaining the observed point-like and diffuse emissions.

Contribution

It introduces a diffusion-based model linking the energy-dependent morphology of HESS J1702-420 to proton propagation dynamics from a single accelerator embedded in a dense cloud.

Findings

Protons with energy-dependent diffusion explain the morphology.

The model reproduces observed fluxes and spatial features.

Proton injection rate aligns with observed gamma-ray emission.

Abstract

HESS J1702-420 is a multi-TeV gamma-ray source with an unusual energy-dependent morphology. The recent H.E.S.S. observations suggest that the emission is well described by a combination of point-like HESS J1702-420A (dominating at highest energies, $\gtrsim$ 30 TeV ) and diffuse ($\sim$ 0.3$^\circ$) HESS J1702-420B (dominating below $\lesssim$ 5TeV) sources with very hard (${\Gamma} \sim 1.5$) and soft (${\Gamma}$ ~2.6) power-law spectra, respectively. Here we propose a model which postulates that the proton accelerator is located at the position of HESS J1702-420A and is embedded into a dense molecular cloud that coincides with HESS J1702-420B. In the proposed model, the VHE radiation of HESS J1702-420 is explained by the pion-decay emission from the continuously injected relativistic protons propagating through a dense cloud. The energy-dependent morphology is defined by the diffusive nature of the low-energy protons propagation, transiting sharply to (quasi) ballistic propagation at higher energies. Adopting strong energy dependence of the diffusion coefficient, $D \propto E^\beta$ with $\beta \geq 1$, we argue that HESS J1702-420 as the system of two gamma-ray sources is the result of the propagation effect. Protons injected by a single accelerator at the rate $Q_0 \simeq 10^{38} \, (n_0/100 \, \rm cm^{-3})^{-1}\, (d/ \, 0.25\,kpc)^{-1} \rm erg/s$ can reasonably reproduce the morphology and fluxes of two gamma-ray components.