Abstract
A maximum likelihood analysis of the NGC 4258 maser positions and velocities reveals a ~2 sigma deviation from Keplerian motion in the projected rotation curve of the high-velocity features, corresponding to a ~9 km/s, or 0.8%, flattening of the LOS velocities with respect to Keplerian motion over the range of the high-velocity masers. While there are a number of potential explanations for this flattening, we argue for pure Keplerian rotation in an inclination-warped disk based on the ability of this model to explain a number of otherwise puzzling features of the system. A radial gradient in the disk inclination of 0.034 mas^{-1} is not only consistent with the observed rotation curve, but it generates a bowl along the near edge of the disk that naturally explains the otherwise puzzling narrow spread in the declinations of the systemic masers. It also explains the existence and location of an apparently recurring flare amongst the systemic masers. There is no significant evidence for non-Keplerian rotation in the inclination-warped disk. An additional implication of the inclination warp is that the disk rises in front of and obscures the central engine at a disk radius of about 8.3 mas, or 0.29 pc. By comparing the observed X-ray column to conditions in the disk at this radius, we argue that the molecular-to-atomic transition occurs just beyond the outermost maser at 0.28 pc and from this we infer an accretion rate of \~10^{-4}alpha M_sun/yr, consistent with the jet-dominated accretion models of Yuan et al. (2002). Our model suggests that most of the observed X-ray column arises in the warped accretion disk at 0.29 pc, and that the maser emission is truncated at large radii predominantly as a result of the molecular-to-atomic phase transition originally proposed by Neufeld & Maloney (1995).
Highlights
A maximum likelihood analysis of the NGC 4258 maser positions and velocities reveals a ∼ 2σ deviation from Keplerian motion in the projected rotation curve of the high-velocity features, corresponding to a ∼ 9 km s−1, or 0.8%, flattening of the LOS velocities with respect to Keplerian motion over the range of the high-velocity masers
While there are a number of potential explanations for this flattening, we argue for pure Keplerian rotation in an inclination-warped disk based on the ability of this model to explain a number of otherwise puzzling features of the system
While there is compelling evidence for a ∼ 8 km s−1 flattening in the projected rotation curve of the high-velocity masers, its physical origin is ambiguous
Summary
In hopes of detecting additional systemic flares, the lowvelocity maser spectrum of NGC4258 was monitored from 1997 January 27 to 1997 June 24 with the 37-meter diameter antenna of the Haystack Observatory. Position-switched total power spectra were calibrated using a system temperature referenced to outside the atmosphere and corrected for elevation dependent antenna gain using a standard model for the antenna. We observed continuum sources 4C39.25 and 1308+326 to calibrate offsets in antenna pointing. To correct for pointing errors within one hour of transit (elevations 78◦), we sampled the peak line intensity every ∼ 10 minutes and rescaled the spectra to achieve a level response. The calibration of the spectrum compiled for each epoch is accurate to ∼ 20%. The rms noise after removal of a spectral baseline was 0.1 to 0.2 Jy per channel for the 11 epochs
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