Morphology of star-forming clumps in ram-pressure stripped galaxies as seen by HST

TL;DR

This study analyzes the morphology of star-forming clumps in galaxies undergoing ram-pressure stripping using Hubble Space Telescope data, revealing how clump properties vary with position and complex size.

Contribution

It provides a detailed morphological characterization of star-forming clumps in stripped galaxies, highlighting the relationship between clump properties and their location within complexes.

Findings

Clump number and size increase with complex size.

More than half of complexes contain no Hα clumps.

Clump displacement correlates with distance from the galactic disk.

Abstract

We characterize the morphological properties of a statistically relevant sample of H$\alpha$ and UV young star-forming clumps and optical complexes, observed with the \textit{Hubble Space Telescope} in six galaxies of the GASP sample undergoing ram-pressure stripping. The catalogs comprise 2406 (323 in the tails) H$\alpha$ clumps, 3750 (899) UV clumps and 424 tail optical complexes. About 15-20\% of the clumps and 50\% of the complexes are resolved in size. We find that more than half of the complexes contain no H$\alpha$ clumps, while most of them contain at least one UV clump. The clump number and size increase with the complex size, while the median complex filling factor is larger for UV clumps ($0.27$) than for H$\alpha$ clumps ($0.10$) and does not correlate with almost any morphological property. This suggests that the clumps number and size grow with the complex keeping the filling factor constant. When studying the position of the clumps inside their complexes, H$\alpha$ clumps, and UV clumps to a lesser extent, show a displacement from the complex center of $0.1-1$ kpc and, in $\sim 60$\% of the cases, they are displaced away from the galactic disk. This is in accordance with the fireball configuration, already observed in the tails of stripped galaxies. Finally, the filling factor and the clump radius increase with the distance from the galactic disk, suggesting that the reciprocal displacement of the different stellar generations increases as a consequence of the velocity gradient caused by ram pressure.