Two devastating earthquakes struck southeastern Turkiye and northwestern Syria on 6 February 2023: an M-w 7.8 mainshock, followed 9 hr later by an M-w 7.6 aftershock. To recover and separate the subsurface geometry and slip distributions along the two earthquake faults, we jointly invert Interferometric Synthetic Aperture Radar, Synthetic Aperture Radar pixel offset tracking, burst overlap interferometry (BOI), Global Navigation Satellite System, and aftershock datasets. We introduce a new Kalman filter-based approach for merging spatially dense azimuth offset (AZO) data with the more precise yet spatially sparse BOI data. This procedure yields improved measurements of the displacements parallel to the near north-south satellite tracks, which are critical for resolving slip along most of the M-w 7.8 fault segments. We optimize the inversion using a new metric for assessing the degree of spatial correlation between the coseismic slip gradients and early aftershocks, resulting in a stable solution honoring the complementarity between the geodetic and aftershock datasets. The analysis suggests that the M-w 7.8 rupture consisted of three large segments and two short fault branches, covering about 300 km along the East Anatolian fault (EAF), whereas the M-w 7.6 rupture consisted of three segments extending for about 160 km along the nearby Surgu fault (SF). On the basis of moment-to-stress-drop scaling relations, we show that the M-w 7.6 stress drop is four times larger than the M-w 7.8 stress drop, consistent with the larger recurrence intervals for M-w > 7 earthquakes on the SF than on the EAF. The moment released during the 2023 M-w 7.8 earthquake is 2-4 times larger than the sum of themoments released during individual historical M-w > 7 earthquakes along the three segments of the 2023 M-w 7.8 earthquake. Thus, when consideringmoment release formultisegment earthquakes, one should note that the final moment of fault coalescence is likely larger than the arithmetic sum of individual segment ruptures.