On the Origin of TeV Gamma-ray Emission from HESS J1834-087

TL;DR

This study investigates the origin of TeV gamma-ray emission from HESS J1834-087, proposing a new pulsar wind nebula origin near W41's center, supported by X-ray observations indicating a potential energetic pulsar.

Contribution

The paper introduces the possibility that a previously unknown pulsar wind nebula, rather than SNR interactions or a known pulsar, powers the TeV emission, based on X-ray evidence.

Findings

Identification of a hard X-ray point source coincident with diffuse emission.

X-ray spectral analysis suggests a highly absorbed, non-thermal source.

Estimated pulsar energy output consistent with observed gamma-ray luminosity.

Abstract

We present an X-ray study of the field containing the extended TeV source HESS J1834-087 using data obtained with the XMM-Newton telescope. Previously, the coincidence of this source with both the shell-type supernova remnant (SNR) W41 and a giant molecular cloud (GMC) was interpreted as favoring pi^0-decay gamma-rays from interaction of the old SNR with the GMC. Alternatively, the TeV emission has been attributed to inverse Compton scattering from leptons deposited by PSR J1833-0827, a pulsar assumed to have been born in W41 but now located 24' from the center of the SNR (and the TeV source). Instead, we argue for a third possibility, that the TeV emission is powered by a previously unknown pulsar wind nebula located near the center of W41. The candidate pulsar is XMMU J183435.3-084443, a hard X-ray point source that lacks an optical counterpart to R>21 and is coincident with diffuse X-ray emission. The X-rays from both the point source and diffuse feature are evidently non-thermal and highly absorbed. A best fit power-law model yields photon index Gamma ~ 0.2 and Gamma ~ 1.9, for the point source and diffuse emission, respectively, and 2-10 keV flux ~ 5 X 10^(-13) ergs/cm^(2)/s for each. At the measured 4 kpc distance of W41, the observed X-ray luminosity implies an energetic pulsar with Edot ~ 10^(36)d_4^2 ergs/s, which is also sufficient to generate the observed gamma-ray luminosity of 2.7 X 10^(34)d_4^2 ergs/s via inverse Compton scattering.