Shay Zucker, Tal Alexander, Stefan Gillessen, Frank Eisenhauer, Reinhard Genzel
Published 2005-09-05Version 1
Stars closely approaching the massive black hole in the center of the Galaxy provide a unique opportunity to probe post-Newtonian physics in a yet unexplored regime of celestial mechanics. Recent advances in infrared stellar spectroscopy allow the precise measurement of stellar Doppler shift curves and thereby the detection of beta-squared post-Newtonian effects (gravitational redshift in the black hole's potential and the transverse Doppler shift). We formulate a detection procedure in terms of a simplified post-Newtonian parametrization. We then use simulations to show that these effects can be decisively detected with existing instruments after about a decade of observations. We find that neglecting these effects can lead to statistically significant systematic errors in the derived black hole mass and distance.
Comments: 4 pages, 3 figures, submitted to The Astrophysical Journal Letters
Journal: Astrophys.J.639:L21-L24,2006
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