Evolution of QPO During Discovery Outburst of MAXI J1834-021: Estimation of Intrinsic Parameters from Spectro-Temporal Study

Abstract

The Galactic transient black hole candidate (BHC) MAXI~J1834-021 was detected for the first time by MAXI/GSC on February 05, 2023 and it was active for next 10~months. A monotonic evolution of low-frequency QPOs from higher to lower frequencies is observed in the middle-phase of the outburst. We study this evolution of the QPO with the propagating oscillatory shock (POS) model, and it suggests the presence of a receding shock. The POS model fit also estimates the mass of the source to be 12.10.3~M. We also study the boradband (0.5-70~keV) nature of the source using archival data of NICER and NuSTAR on March 10, 2023 with the both phenomenological (combined disk blackbody plus powerlaw) and physical (nthComp, kerrbb, TCAF) models. The mass of the BHC estimated by the kerbb and TCAF models is found to be consistent with POS model fits as well as reported in our recent work. Combining all these methods, we predict mass of the source as 12.3+1.1-2.0~M. The kerbb model fit also estimates the spin, distance, and inclination of the source to be 0.13+0.03-0.02, 9.2+0.4-0.9~kpc, and 80.0+2.7-6.0, respectively. The combined spectral study suggests harder spectral state of the source with a higher dominance of the sub-Keplerian halo accretion rate over the Keplerian disk rate. The consistency of the observed frequency of the QPO with that of obtained from the TCAF model fitted shock parameters, confirms shock oscillation as the origin of the QPO.