A Delayed Radio Flare Traces Kinetic Energy Injection in the SMBHB Candidate SDSS~J143016.05+230344.4
Abstract
SDSS~J143016.05+230344.4 (z=0.08105) has been proposed as a candidate pre-coalescence supermassive black hole binary and shows remarkable multiwavelength variability. Its radio evolution provides a direct probe of the compact emitting region and of the physical origin of the late-time activity. We aim to localize the variable radio emission, characterize its spectral evolution, and constrain whether the radio brightening is produced by a newly emerging compact component, external absorption, or dissipation in a structured circumnuclear environment. At all epochs, the radio emission is dominated by a single unresolved milliarcsecond core with T B 107 K, constraining the variable emission to 0.3 pc. The broadband spectra require two synchrotron self-absorbed components: a persistent low-frequency component with p,steady ≈ 0.74 GHz and S p,steady ≈ 1.22 mJy, and a flare component whose turnover evolves from (6.35 GHz, 0.18 mJy) in 2022 February-May to (8.61 GHz, 0.38 mJy) in 2022 December, and then to (5.83 GHz, 0.25 mJy) in 2023 March-April. The flare contribution at 15 GHz reaches 80\% and matches the near-epoch VLBI recovery fraction, showing that the high-frequency brightening arises from a newly formed compact synchrotron component. A second brightening of the 15.2 GHz VLBI core is detected between 2023 September and 2024 February, while the source remains unresolved. Equipartition scalings imply characteristic radii of 5 × 10-4 pc for the flare and 9 × 10-3 pc for the steady component, and indicate a steep inner circumnuclear density profile, n R-1.7. The delayed radio flare is best explained by dissipation in an outflow or jet-base disturbance propagating through a structured circumnuclear medium.
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