Prosto Science
The analysis yielded an estimate of approximately 200 million solar masses (2 × 108 M⊙), likely corresponding to the secondary black hole in the proposed OJ 287 binary system.
The Swift/XRT data set for OJ 287 consists of many short exposures, typically around one kilosecond each. Individually, most of these observations contain too few counts for reliable spectral modelling, making it difficult to trace changes in the X-ray spectrum through standard fits to each exposure.
The main analytical challenge was therefore to combine observations without washing out the physical dependence on source flux. The data were grouped by flux and averaged within each group, producing statistically robust spectra suitable for detailed modelling.
OJ 287 is a blazar and a long-standing candidate for hosting a binary system of supermassive black holes. Swift/XRT has monitored the source extensively, but the observations are distributed across many short and fragmented pointings. Their combined spectral evolution provides a way to investigate the physical processes operating close to the central engine.
This analysis was undertaken in response to a request from a theoretical astrophysics group studying accretion-flow models. The central prediction was a characteristic relation between the X-ray photon index and the inferred accretion rate: a rise at lower values followed by saturation at higher values.
Testing this behaviour required spectra with enough counts for stable modelling. Because the individual Swift/XRT pointings were too short, a custom flux-selected averaging procedure had to be developed.
All available Swift/XRT observations of OJ 287 were reprocessed in a uniform way. The exposures were then sorted by source flux and combined within defined flux intervals, producing averaged spectra with sufficient statistical quality for physical modelling.
Each averaged spectrum was analysed with the bulk-motion Comptonization (BMC) model. The resulting relation between photon index and BMC normalization was then compared with reference black-hole systems using the established scaling method.
The reconstructed relation shows a clear rise of the photon index at lower BMC normalization and saturation at higher values—the characteristic behaviour required for the scaling analysis.
Applying the scaling relation yielded an independent black-hole mass estimate of approximately 2 × 108 M⊙ (about 200 million solar masses). In the physical interpretation adopted in the study, this mass most likely corresponds to the secondary component of the proposed OJ 287 binary system.
Later studies of OJ 287 by Valtonen et al. (2023) and Komossa et al. (2023) also arrived at black-hole mass scales of order 108 M⊙, using different physical models and observational approaches. Although the interpretations differ, the numerical estimates are broadly comparable.
Kuznetsov, S. 2024, MNRAS, 535, 3732 —
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Valtonen, M. J., et al. 2023, MNRAS, 525, 1153 —
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Komossa, S., et al. 2023, MNRAS Letters, 522, L84 —
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