The variable X-ray emission of PSR B0943+10

TL;DR

This study reveals that PSR B0943+10 exhibits mode-dependent X-ray emission, with higher flux and non-thermal components during its radio-fainter Q mode, providing insights into pulsar magnetosphere processes.

Contribution

First detailed X-ray analysis showing mode-dependent emission in PSR B0943+10, linking radio states to thermal and non-thermal X-ray components.

Findings

X-ray flux doubles in Q mode compared to B mode

Detection of 50% pulsed X-ray emission in Q mode

Thermal X-ray emission from a hot spot in B mode

Abstract

The old pulsar PSR B0943+10 (P=1.1 s, characteristic age tau=5 Myr) is the best example of mode-switching radio pulsar. Its radio emission alternates between a highly organized state with regular drifting subpulses (B mode) and a chaotic emission pattern (Q mode). We present the results of XMM-Newton observations showing that the X-ray properties of PSR B0943+10 depend on its radio state (Hermsen et al. 2013). During the radio fainter state (Q mode) the X-ray flux is more than a factor two larger than during the B-mode and X-ray pulsations with about 50% pulsed fraction are detected. The X-ray emission of PSR B0943+10 in the B-mode is well described by thermal emission with blackbody temperature kT=0.26 keV coming from a small hot spot with luminosity of 7x10^28 erg/s, in good agreement with the prediction of the partially screened gap model, which also explains the properties of the radio emission in this mode. We derived an upper limit of 46% on the X-ray pulsed fraction in the B-mode, consistent with the geometry and viewing angle of PSR B0943+10 inferred from the radio data. The higher flux observed during the Q-mode is consistent with the appearance of an additional component with a power-law spectrum with photon index 2.2. We interpret it as pulsed non-thermal X-rays produced in the star magnetosphere. A small change in the beaming pattern or in the efficiency of acceleration of the particles responsible for the non-thermal emission can explain the reduced flux of this component during the radio B-mode.