📝 SummarXiv

Abstract

Recent observations with the James Webb Space Telescope (JWST) of massive galaxies at ages below 1 Gyr pose a challenge to standard models of galaxy formation, which predict significantly longer assembly timescales. One possible explanation is that active galactic nuclei (AGN) drive large scale outflows that accelerate galaxy growth. To test this scenario in the local Universe, we analyzed Gaia DR3 data for stars within 5 kpc of the Galactic center, computing galactocentric radial velocities (v_radial_gc) in 27 spatial sectors covering the entire Galaxy, with radial binning of 0.25 kpc. Coordinate transformations and velocity calculations were performed using the Astropy library. We find that 21 of 27 sectors exhibit statistically significant outward motions of 3-50 km/s, while one quadrant shows negative velocities, likely related to the configuration of an activity zone and/or the Galactic bar. Both disk and halo populations also display small but significant mean expansion of 3-9 km/s (p<0.01). These results are consistent with our previous studies, where globular clusters showed outward velocities of 17-31 km/s up to 12 kpc, and axisymmetric analyses of Gaia DR3 stars indicated expansion of ~19 km/s to 5 kpc. Taken together, the evidence suggests that the Milky Way exhibits measurable central expansion, potentially reflecting AGN-driven feedback. This interpretation departs from standard theory and should be regarded as preliminary, requiring further study. However, if confirmed, such expansion could provide a natural explanation for the rapid appearance of massive galaxies observed by JWST.