Investigating MAXI J1752-457 with NuSTAR in the aftermath of a superburst

TL;DR

This study uses NuSTAR observations to analyze the spectral and timing properties of MAXI J1752-457 after a superburst, revealing insights into its accretion state and spectral evolution.

Contribution

First detailed spectral and timing analysis of MAXI J1752-457 post-superburst using NuSTAR, highlighting its accretion state and spectral characteristics.

Findings

Blackbody temperature around 0.60 keV with no significant change over a day.

Source variability dominated by red noise in the power law component.

Photon index approximately 4, indicating evolving electron energy distribution.

Abstract

We present two NuSTAR observations of the X-ray transient, MAXI J1752-457, following a superburst which was observed by MAXI/GSC in November, 2024. NuSTAR follow-up confirmed that MAXI J1752-457 is coincident with the previously observed Einstein Probe source, EP240809a. We performed a spectral analysis of the source during both NuSTAR observations, and we find that the hard X-ray spectra are consistent with the inclusion of a spherical blackbody component and a steep, non-thermal, power law component. At about 79 hours after the onset of the superburst, we find a blackbody temperature of $kT_\mathrm{bb}=0.60\pm0.1$ keV and $R_\mathrm{bb}/D_{8}=6.0^{+0.4}_{-0.3}$ km (not including corrections for scattering in the neutron star atmosphere), where $D_{8}$ is the source distance, which is not yet known, in units of 8 kpc. We found that the blackbody temperature did not change significantly in the one day interval between successive NuSTAR observations, and we performed an energy-resolved timing analysis which showed that the source variability was dominated by red noise in the power law component, suggesting coupling with an accretion disk. We infer that the source had entered an accretion-powered flux state. Furthermore, we measure a photon index of $\Gamma\approx4$, much steeper than those typically observed during accretion onto neutron stars at similar luminosities. This is suggestive of ongoing evolution of the electron energy distribution responsible for the power law component several days after the superburst, but the lack of hard X-ray observations prior to and throughout the superburst make it difficult to present a conclusive physical interpretation of this result.