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Abstract

We present the first X-ray polarimetry observations of a redback millisecond pulsar binary, \src, with the Imaging X-ray Polarimetry Explorer (IXPE). Redbacks are compact binaries in which a rotation-powered millisecond pulsar interacts with a non-degenerate companion via an intrabinary shock, forming ideal laboratories for probing pulsar winds and relativistic shock physics, where ordered magnetic fields and particle acceleration shape the observed radiation. We conduct a spectro-polarimetric analysis combining IXPE data with archival Chandra, XMM-Newton, NuSTAR, and Swift observations. We explore two limiting magnetic field configurations, parallel and perpendicular to the bulk flow, and simulate their expected polarization signatures using the {\tt 3DPol} radiative transport code. To account for the rapid rotation of the polarization angle predicted by these models, we implement a phase-dependent Stokes alignment procedure that preserves the polarization degree while correcting for phase-rotating PA. We also devise a new maximum-likelihood fitting strategy to determine the phase-dependence of the polarization angle by minimizing the polarization degree uncertainty. This technique shows a hint the binary may be rotating clockwise relative to the celestial north pole. We find no significant detection of polarization in the IXPE data, with PD<51% at 99% confidence level. Our results excludes the high-polarization degree scenario predicted by the perpendicular field model during the brightest orbital phase bin. Simulations show that doubling the current exposure would make the parallel configuration detectable. The new PA rotation technique is also applicable to IXPE data of many sources whose intrinsic PA variation is apriori not known but is strictly periodic.