Sean N. Pike, Hitoshi Negoro, Douglas Buisson, Benjamin Coughenour, Julian Gerber, Aarran W. Shaw, Mutsumi Sugizaki, John A. Tomsick

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 confirm that the hard X-ray spectra are consistent with the inclusion of a spherical blackbody 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. Furthermore, we report a hard X-ray excess which is fit well by a power law with photon index $\Gamma\approx4$, much steeper than those typically seen during accretion onto neutron stars at similar luminosities. We infer that the electron energy distribution in the Comptonizing medium which gives rise to the power law component differs significantly compared to purely accretion-powered neutron star transients even several days after the onset and rapid decay of superbursts. We also performed an energy-resolved timing analysis which showed that the source variability was dominated by red noise in the Comptonization component, suggesting coupling with an accretion disk, rather than being seeded by thermal emission from the neutron star surface.