Evidence for High-Frequency QPOs with a 3:2 Frequency Ratio from a 5000 Solar Mass Black Hole

Abstract

Following the discovery of 3:2 resonance quasi-periodic oscillations (QPOs) in M82X-1 (Pasham et al. 2014), we have constructed power density spectra (PDS) of all 15 (sufficiently long) XMM-Newton observations of the ultraluminous X-ray source NGC1313X-1 (LX ≈ 2×1040 erg/sec). We detect a strong QPO at a frequency of 0.290.01 Hz in data obtained on 2012 December 16. Subsequent searching of all the remaining observations for a 3:2/2:3 frequency pair revealed a feature at 0.460.02 Hz on 2003 Dec 13 (frequency ratio of 1.590.09). The global significance of the 0.29 Hz feature considering all frequencies between 0.1 and 4 Hz is > 3.5 σ. The significance of the 0.460.02 Hz QPO is > 3.5σ for a search at 2/3 and 3/2 of 0.29 Hz. We also detect lower frequency QPOs (32.92.6 and 79.71.2 mHz). All the QPOs are super-imposed on a continuum consisting of flat-topped, band-limited noise, breaking into a power-law at a frequency of 163 mHz and white noise at 0.1 Hz. NGC1313X-1's PDS is analogous to stellar-mass black holes' (StMBHs) PDS in the so-called steep power-law state, but with the respective frequencies (both QPOs and break frequencies) scaled down by a factor of 1000. Using the inverse mass-to-high-frequency QPO scaling of StMBHs, we estimate NGC1313X-1's black hole mass to be 50001300 M, consistent with an inference from the scaling of the break frequency. However, the implied Eddington ratio, LEdd > 0.030.01, is significantly lower compared to StMBHs in the steep power-law state (LEdd 0.2).