Temporal X-ray Properties of Galactic Black Hole Candidates: Observational Data and Theoretical Models

I review the observed temporal X-ray properties of Galactic black hole candidates and the status of theoretical modeling of these properties. Like spectral X-ray properties, which has so far attracted most of the attention, the temporal properties, such as power spectral density, hard X-ray time lags, and coherence functions, contain information on some of the same physical properties of inverse Comptonization processes, which are generally believed to be responsible for producing hard X-ray emission in black hole candidates. In addition, the temporal properties add new information about the size of the Comptonizing region and perhaps its density structure. Therefore, the spectral and temporal properties taken together may help break the degeneracy, intrinsic to most spectral studies, in determining the temperature and optical depth of hot electrons. Moreover, significant insights might be gained into the dynamics of mass accretion in black hole candidates from the inferred density structure of accreted gas (from the temporal properties). Unfortunately, until very recently little has been done to quantitatively model the observed temporal properties of black hole candidates. I will discuss the recently proposed models, which have been formulated in the context of thermal Comptonization, and compare them to the data. Emphasis will be made on simultaneous studies of the observed spectral and temporal properties, the ultimate approach to studying X-ray production mechanisms in Galactic black holes.