A large, long-lived, slowly-expanding superbubble across the Perseus Arm
Bingqiu Chen, Guangxing Li, Haibo Yuan, Maosheng Xiang, Jixuan Zhou, Pinjian Chen, Martin Krause, Ashley Coombs
TL;DR
This study identifies and characterizes the Giant Oval Cavity as a large, ~1 kpc-scale superbubble in the Perseus Arm, traced by a population of young O-B2 stars from Gaia and LAMOST. The cavity exhibits a slow expansion with v_exp ≈ 6.2 km s−1 and a substantial transverse motion, consistent with a dynamical age of ~80 Myr and a vertical expansion of ~8.5 km s−1, indicating a coherent feedback-driven structure. A quasi-stationary framework is developed, showing that the SN energy input recurs on timescales shorter than Galactic shear and turbulent erosion (t_SN < t_shear < t_survival), with an energy budget requiring ~400 SNe to sustain the cavity. The work links stellar feedback to large-scale ISM dynamics, aligning with JWST observations of giant bubbles and highlighting how repeated supernovae can maintain expansive cavities against shear and turbulence in galactic disks.
Abstract
Stellar feedback is a crucial mechanism in galactic evolution, as demonstrated by the widespread bubbles observed with JWST. In this study, we combine data from Gaia and LAMOST to obtain a sample of young O-B2 stars with full three-dimensional velocity information. Focusing on the largest known superbubble in the Milky Way, we identify groups of O-B2 stars at its periphery, exhibiting a transverse velocity of 25.8 km/s and an expansion velocity of 6.2 km/s. Using these velocities, we calculate a crossing time t_cross ~ 20 Myr and an expansion timescale t_expansion ~ 80 Myr. We estimate a survival timescale t_survival ~ 250 Myr and a supernova interval t_SN ~ 0.1 Myr. Together with the Galactic shear timescale t_shear ~ 30 Myr, these values satisfy t_SN < t_shear < t_survival. The energy and momentum from supernovae are sufficient to sustain the bubble's growth against ambient pressure. This indicates that repeated supernovae replenish energy faster than shear and turbulent distort the cavity. Our analysis classifies the Giant Oval Cavity as a large, quasi-stationary superbubble, similar to the Phantom Bubble observed by JWST, stabilised by the interplay between stellar feedback and Galactic disk dynamics.
