Abstract This study presents a time-resolved spectro-polarimetric analysis of GX 17+2 using IXPE, NICER and NuSTAR observations. Spectral modelling with constant× edge× tbabs (nthcomp+ diskbb+ relxillNS) indicates that the source was in a soft spectral state, and accreting at super-Eddington luminosity. Time-resolved PCUBE analysis shows that the polarization degree (PD) and polarization angle (PA) remain nearly constant across the 2. 0−8. 0 keV energy range, suggesting an aligned geometry between the spin and the binary orbital axes of the neutron star. Energy-resolved PCUBE analysis further indicates that the blackbody emission component most likely originates from the boundary layer. The spectro-polarimetric analysis confirms that the reflected emission contributes a PD 20percnt, consistent with theoretical expectations. In contrast, the Comptonizing medium exhibits a PD of ~0. 8 −1. 4percnt, while the accretion disc shows a PD of ~1. 4 −3. 2percnt in the 2. 0−8. 0 keV energy range, exceeding theoretical predictions. Energy-resolved spectro-polarimetric analysis hints at excess disc polarization, possibly associated with the formation of a slim disc and the presence of disc wind under super-Eddington accretion conditions. Both time- and energy-resolved polarization measurements reveal a rotation of the PA for the diskbb and nthcomp components in the 3. 5−8. 0 keV energy range, suggesting a coupling between the soft and hard polarized emission components. Our results indicate that while the geometry of GX 17+2 is aligned, the emergent hard X-ray emission is significantly influenced by inner disc outflows. The nearly constant PD across energy and time further points to a complex interplay among the accretion disc, Comptonization, and reflection components.
Lavanya et al. (Mon,) studied this question.
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