A Warm Molecular Hydrogen Tail Due to Ram Pressure Stripping of a Cluster Galaxy

TL;DR

This paper reports the discovery of a warm molecular hydrogen tail caused by ram-pressure stripping in a cluster galaxy, revealing gas loss, shock heating, and localized star formation outside the galaxy.

Contribution

It provides the first detailed observation of a warm H_2 tail in a cluster galaxy and estimates the gas loss rate due to ram-pressure stripping.

Findings

Discovered a 20 kpc warm H_2 tail with 4*10^7 solar masses.

Detected shock-heated gas and localized star formation in the tail.

Estimated gas loss rate of 2-3 solar masses per year.

Abstract

We have discovered a remarkable warm (130-160 K) molecular hydrogen tail with a H_2 mass of approximately 4*10^7 solar masses extending 20 kpc from a cluster spiral galaxy, ESO 137-001, in Abell 3627. At least half of this gas is lost permanently to the intracluster medium, as the tail extends beyond the tidal radius of the galaxy. We also detect a hot (400-550 K) component in the tail that is approximately 1% of the mass. The large H_2 line to IR continuum luminosity ratio in the tail indicates that star formation is not a major excitation source and that the gas is possibly shock-heated. This discovery confirms that the galaxy is currently undergoing ram-pressure stripping, as also indicated by its X-ray and Halpha tails found previously. We estimate the galaxy is losing its warm H_2 gas at a rate of ~ 2-3 solar masses per year. The true mass loss rate is likely higher if we account for cold molecular gas and atomic gas. We predict that the galaxy will lose most of its gas in a single pass through the core and place a strong upper limit on the ram-pressure timescale of 1 Gyr. We also study the star-forming properties of the galaxy and its tail. We identify most of the previously discovered external Halpha sources within the tail in our 8 um data but not in our 3.6 um data; IRS spectroscopy of the region containing these Halpha sources also reveals aromatic features typically associated with star formation. From the positions of these HII regions, it appears that star formation is not occurring throughout the molecular hydrogen tail but only immediately downstream of the galaxy. Some of these HII regions lie outside the tidal radius of the galaxy, indicating that ram-pressure stripping can be a source of intracluster stars.