First Detection of 12CO (1--0) Emission from Two Narrow-Line Seyfert 1 Galaxies

TL;DR

This study reports the first detection of CO emission in two narrow-line Seyfert 1 galaxies, revealing their molecular gas content and implications for bulge and black hole coevolution.

Contribution

It provides the first CO(1--0) observations of NLS1s, estimating their molecular gas masses and analyzing bulge growth and coevolution with black holes.

Findings

Detected CO emission in two NLS1s with significant molecular gas masses.

Found the bulge growth in these NLS1s is limited before black hole growth.

Observed a discrepancy between star formation and black hole accretion rates.

Abstract

In order to investigate how the growth of galactic bulges progresses with the growth of central black holes (BHs), we observed molecular gas (fuel for the coming star formation) in possibly young active galaxies, narrow-line Seyfert 1 galaxies (NLS1s). We present the results of radio observations of 12CO(1--0) using the Nobeyama Millimeter Array (with 2--4 kpc spatial resolution) for two FIR-bright NLS1s, yielding the first detection of their CO emission. Corresponding molecular--gas masses M(H2) of (1-3) X 109 Msun are the 2nd and 4th largest ones among NLS1s. By estimating dynamical masses and bulge masses M(bulge) for these two NLS1s using CO channel map and CO line widths, we found M(H2) amount to 0.13--0.35 of these masses. Taking account the star formation efficiency (~ 0.1), the increase in M(bulge) in those NLS1s in the near future (~< 10^{7.5} yr) is expected not to be a huge fraction (1--5% of the preexisting stars). Bulge growth may have finished before BH growth, or bulge--BH coevolution may proceed with many, occasional discrete events, where one coevolution event produces only a small amount of mass growth of BHs and of bulges. We also discuss the ratios of star-formation rate--to--gas accretion rate onto BHs, finding that two NLS1s have very small ratios (~ 1) compared with the M(bulge)/M(BH) ratios found in active and inactive galaxies (~ 700). This huge difference suggests either the non-overlapped coevolution, long star formation duration or temporarily high accretion rate during NLS1 phase.