Probing the Peculiar Behavior of GRS 1915+105 at Near-Eddington Luminosity

Abstract

To understand the nature of supercritical accretion, we systematically analyze the RXTE/PCA data of GRS 1915+105 in its quasi-steady states, by choosing data with small variability during 1999 -- 2000. We apply a multicolor disk plus a thermal Comptonization model and take into consideration accurate interstellar absorption, a reflection component, and absorption features from the disk wind self-consistently. There is a strong correlation between the inner disk temperature and the fraction of the disk component. Most of the Comptonization-dominated spectra show T in 1 keV with a high electron temperature of >10 keV, which may correspond to the very high state in canonical black hole X-ray binaries (BHBs). By contrast, the disk-dominated spectra have T in 2 keV with a low temperature (<10 keV) and optically thick Comptonization, and show two separate branches in the (L -- T in) diagram. The lower branch clearly follows the L T in4-track. Furthermore, applying the extended disk blackbody model, we find that 9 out of 12 datasets with disk luminosity above 0.3 L E prefer a flatter temperature gradient than that in the standard disk (p < 0.7). We interpret that, in the lower branch, the disk extends down to the innermost stable circular orbit, and is most probably in the slim disk state. A rapidly spinning black hole can explain both the lack of the L T in2-track and a high value of spectral hardening factor ( 4) that would be required for a non-rotating black hole. The spectra in the upper branch are consistent with the picture of a truncated disk with low temperature Comptonization. This state is uniquely observed from GRS 1915+105 among BHBs, which may be present at near-Eddington luminosity.