The Black Hole Mass and Photometric Components of NGC 4826

Abstract

We present IR photometry and HST imaging and spectroscopy of Sab galaxy NGC 4826. Schwarzschild dynamical modeling is used to measure its central black hole mass M. Photometric decomposition is used to enable a comparison of M to published scaling relations between black hole masses and properties of host bulges. This decomposition implies that NGC 4826 contains classical and pseudo bulges of approximately equal mass. The classical bulge has best-fit S\'ersic index n=3.27. The pseudobulge is made up of three parts, an inner lens (n=0.18 at r4), an outer lens (n=0.17 at r 45), and a n=0.58 component required to match the surface brightness between the lens components. The total V-band luminosity of the galaxy is MVT=-21.07, the ratio of classical bulge to total light is B/T0.12, and the ratio of pseudobulge to total light is PB/T0.13. The outer disk is exponential (n=1.07) and makes up D/T=0.75 of the light of the galaxy. Our best-fit Schwarzschild model has a black hole mass with 1σ uncertainties of M=8.4+1.7-0.6×106\ M and a stellar K-band mass-to-light ratio of K=0.460.03\ M\ L-1 at the assumed distance of 7.27 Mpc. Our modeling is marginally consistent with M=0 at the 3σ limit. These best-fit parameters were calculated assuming the black hole is located where the velocity dispersion is largest; this is offset from the maximum surface brightness, probably because of dust absorption. The black hole mass -- one of the smallest measured by modeling stellar dynamics -- satisfies the well known correlations of M with the K-band luminosity, stellar mass, and velocity dispersion of the classical bulge only in contrast to total (classical plus pseudo) bulge luminosity.