Diffuse X-ray-emitting Gas in Major Mergers

TL;DR

This study analyzes diffuse X-ray emission in 49 merging galaxy pairs using Chandra data, finding that hot gas luminosity correlates with star formation rate and remains steady across merger stages, with some variations in specific galaxy types.

Contribution

First comprehensive analysis of diffuse X-ray emission in a large sample of merging galaxies, linking hot gas properties to star formation and merger stage.

Findings

L(X)(gas)/SFR ratio is consistent with normal spirals for most galaxies.

Post-starburst remnants show enhanced hot gas emission relative to SFR.

No significant influence of active galactic nuclei on hot gas content.

Abstract

Using archived data from the Chandra X-ray telescope, we have extracted the diffuse X-ray emission from 49 equal-mass interacting/merging galaxy pairs in a merger sequence, from widely separated pairs to merger remnants. After removal of contributions from unresolved point sources, we compared the diffuse thermal X-ray luminosity from hot gas (L(X)(gas)) with the global star formation rate (SFR). After correction for absorption within the target galaxy, we do not see strong trend of L(X)(gas)/SFR with SFR or merger stage for galaxies with SFR > 1 M(sun) yr^-1. For these galaxies, the median L(X)(gas)/SFR is 5.5 X 10^39 ((erg s^-1)/M(sun) yr^-1)), similar to that of normal spiral galaxies. These results suggest that stellar feedback in star forming galaxies reaches an approximately steady state condition, in which a relatively constant fraction of about 2% of the total energy output from supernovae and stellar winds is converted into X-ray flux. Three late-stage merger remnants with low SFRs and high K band luminosities (L(K)) have enhanced L(X)(gas)/SFR; their UV/IR/optical colors suggest that they are post-starburst galaxies, perhaps in the process of becoming ellipticals. Systems with L(K) < 10^10 L(sun) have lower L(X)(gas)/SFR ratios than the other galaxies in our sample, perhaps due to lower gravitational fields or lower metallicities. We see no relation between L(X)(gas)/SFR and Seyfert activity in this sample, suggesting that feedback from active galactic nuclei is not a major contributor to the hot gas in our sample galaxies.