ALMA observation of the disruption of molecular gas in M87

TL;DR

ALMA observations reveal that AGN activity in M87 disrupts or excites molecular gas, affecting the cold gas reservoir essential for star formation.

Contribution

This study provides direct ALMA evidence of molecular gas disruption by AGN activity in M87, linking radio lobe interactions to cold gas destruction or excitation.

Findings

Detected extended CO (2-1) emission near M87's nucleus.

Molecular gas mass estimated at 4.7 x 10^5 M_sun.

Molecular gas is located outside the radio lobe, indicating disruption.

Abstract

We present the results from ALMA observations centred $40^{\prime\prime}$ (3 kpc in projection) southeast of the nucleus of M87. We report the detection of extended CO (2-1) line emission with a total flux of $(5.5 \pm 0.6) \times 10^{-18}$ erg s$^{-1}$ cm$^{-2}$ and corresponding molecular gas mass $M_{H_2}=(4.7 \pm 0.4) \times 10^5 M_\odot$, assuming a Galactic CO to H$_2$ conversion factor. ALMA data indicate a line-of-sight velocity of $-129\pm3$ km s$^{-1}$, in good agreement with measurements based on the [CII] and H$\alpha$+[NII] lines, and a velocity dispersion of $\sigma=27\pm3$ km s$^{-1}$. The CO(2-1) emission originates only outside the radio lobe of the AGN seen in the 6~cm VLA image, while the filament prolongs further inwards at other wavelengths. The molecular gas in M87 appears to be destroyed or excited by AGN activity, either by direct interaction with the radio plasma, or by the shock driven by the lobe into the X-ray emitting atmosphere. This is an important piece of the puzzle in understanding the impact of the central AGN on the amount of the coldest gas from which star formation can proceed.