The over-massive black hole in NGC 1277: New constraints from molecular gas kinematics

J. Scharwächter, F. Combes, P. Salomé, M. Sun, M. Krips

Published 2015-07-08Version 1

We report the detection of CO(1-0) emission from NGC 1277, a lenticular galaxy in the Perseus Cluster, which has been proposed to host a $(1.3-1.7) \times 10^{10}\ M_\odot$ black hole (BH) based on stellar kinematic measurements. The CO(1-0) emission, observed with the IRAM Plateau de Bure Interferometer (PdBI) using both, a more extended (~1-arcsec resolution) and a more compact (~2.5-arcsec resolution) configuration, is likely to originate from the dust lane encompassing the galaxy nucleus at a distance of 0.9 arcsec (~320 pc). The spatially-unresolved double-horned CO(1-0) profile found at 2.5-arcsec resolution is likely to trace gas orbiting in the dust lane with rotational velocities of ~520 km s$^{-1}$, indicative of an enclosed mass of ~$2 \times 10^{10}\ M_\odot$. Based on models with realistic mass distributions, the CO(1-0) kinematics is found to be consistent with a ~$1.7 \times 10^{10}\ M_\odot$ BH, while a less massive BH is still possible assuming a large stellar mass-to-light ratio. The strongest CO(1-0) component, centred at ~+500 km s$^{-1}$, is detected at 1-arcsec resolution. It shows an offset from the underlying continuum peak and may originate from a gas clump near the eastern orbital node of the dust lane. The extended 2.6-mm continuum emission is likely associated with a weak AGN, possibly characterized by an inverted radio-to-millimetre spectral energy distribution. Literature radio and X-ray data indicate that an ultra-massive BH in NGC 1277 would not only be over-massive with respect to the BH scaling relations, but also with respect to the fundamental plane of BH activity.