A deep $XMM-Newton$ observation of the X-Persei-like binary system CXOU J225355.1+624336

TL;DR

This paper presents a detailed X-ray study of the binary system CXOU J225355.1+624336, confirming its classification as a persistent Be X-ray binary with consistent flux, spin-down behavior, and spectral characteristics over multiple observations.

Contribution

The study provides the first comprehensive analysis of CXOU J225355.1+624336 using XMM-Newton data, including spectral and timing analysis, and confirms its nature as a low-luminosity, persistent Be X-ray binary.

Findings

Consistent flux level across multiple observations.

Measured pulse period of 46.753 seconds with steady spin-down.

Spectral analysis favors non-thermal emission models, disfavors thermal components.

Abstract

We report on the follow-up $XMM-Newton$ observation of the persistent X-ray pulsar CXOU J225355.1+624336, discovered with the CATS@BAR project on archival $Chandra$ data. The source was detected at $f_{\rm X}$(0.5-10 keV) = 3.4$\times 10^{-12}$ erg cm$^{-2}$ s$^{-1}$, a flux level which is fully consistent with the previous observations performed with $ROSAT$, $Swift$, and $Chandra$. The measured pulse period $P$ = 46.753(3) s, compared with the previous measurements, implies a constant spin down at an average rate $\dot P = 5.3\times 10^{-10}$ s s$^{-1}$. The pulse profile is energy dependent, showing three peaks at low energy and a less structured profile above about 3.5 keV. The pulsed fraction slightly increases with energy. We described the time-averaged EPIC spectrum with four different emission models: a partially covered power law, a cut-off power law, and a power law with an additional thermal component (either a black body or a collisionally ionized gas). In all cases we obtained equally good fits, so it was not possible to prefer or reject any emission model on the statistical basis. However, we disfavour the presence of the thermal components, since their modeled X-ray flux, resulting from a region larger than the neutron star surface, would largely dominate the X-ray emission from the pulsar. The phase-resolved spectral analysis showed that a simple flux variation cannot explain the source variability and proved that it is characterized by a spectral variability along the pulse phase. The results of the $XMM-Newton$ observation confirmed that CXOU J225355.1+624336 is a BeXB with a low-luminosity ($L_{\rm X} \sim 10^{34-35}$ erg s$^{-1}$), a limited variability, and a constant spin down. Therefore, they reinforce the source classification as a persistent BeXB.