Determination of masses of the central black holes in NGC524 and NGC2549 using Laser Guide Star Adaptive Optics

TL;DR

This study demonstrates the use of Laser Guide Star Adaptive Optics for high-resolution measurement of supermassive black hole masses in NGC524 and NGC2549, combining innovative observational techniques with dynamical modeling.

Contribution

It introduces an open loop LGS AO technique and combines NIFS and SAURON data for improved SMBH mass determination in galaxies with different core profiles.

Findings

Measured SMBH masses: NGC524 ~8.3x10^8 Msun, NGC2549 ~1.4x10^7 Msun.

High-quality AO observations achieved with 0.17-0.23" resolution.

SAURON data significantly improves mass-to-light ratio accuracy.

Abstract

[abridged] We present observations of NGC524 and NGC2549 with LGS AO obtained at GEMINI North telescope using the NIFS IFU in the K band. The purpose of these observations, together with previously obtained observations with the SAURON IFU, is to determine the masses (Mbh) of the supermassive black holes (SMBH). The targeted galaxies were chosen to have central light profiles showing a core (NGC524) and a cusp (NGC2549), to probe the feasibility of using the galaxy centre as the NGS required for LGS AO. We employ an innovative `open loop' technique. The data have spatial resolution of 0.23" and 0.17" FWHM, showing that high quality LGS AO observations of these objects are possible. We construct axisymmetric three-integral dynamical models which are constrained with both the NIFS and SAURON data. The best fitting models yield Mbh=(8.3 +2.7 -1.3) x 10^8 Msun for NGC524 and Mbh=(1.4 +0.2 -1.3) x 10^7 Msun for NGC2549 (all errors are at the 3 sigma CL). We demonstrate that the wide-field SAURON data play a crucial role in the M/L determination increasing the accuracy of M/L by a factor of at least 5, and constraining the upper limits on Mbh. The NIFS data are crucial in constraining the lower limits of Mbh and in combination with the large scale data reducing the uncertainty by a factor of 2 or more. We find that the orbital structure of NGC524 shows significant tangential anisotropy, while at larger radii both galaxies are consistent with having almost perfectly oblate velocity ellipsoids. Tangential anisotropy in NGC524 coincides with the size of SMBH sphere of influence and the core region in the light profile. We test the accuracy to which Mbh can be measured using seeings obtained from typical LGS AO observations, and conclude that for a typical conditions and Mbh the expected uncertainty is of the order of 50%.