High precision mapping of H2O megamaser emissions from active galaxies have revealed more than a dozen of Keplerian H2O aser disks that enable a ~4% Hubble constant measurement and provide accurate black hole masses. The maser disks that allow for these important astrophysical applications usually display clear inner and outer edges at sub-parsec scales. It is still unclear what causes these boundaries and how their radii are determined. To understand whether the physical conditions favorable for population inversion of H2O molecules can determine the inner and outer radii of a maser disk, we examine the distributions of gas density and X-ray heating rate in a warped molecular disk described by power-law surface density profile. With a suitable choice of the disk mass, we find that the outer radius R_out of the maser disk predicted from our model can match the observed value, with R_out mainly determined by the maximum heating rate or the minimum density for efficient maser action, depending on the combination of the Eddington ratio, black hole mass and disk mass. Our analysis also suggests that the inner edge of a maser disk often lie close to the dust sublimation radius, suggesting that the physical conditions of the dusts may play a role in defining inner boundary of the disk. Finally, our model predicts that H2O "gigamaser" disks could possibly exist at the center of high-z quasars, with disk size of >~10-30 pc.
Comment: To be submitted, 13 pages, 5 figures, 2 tables