Identifying Long Radio Transients with Accompanying X-Ray Emission as Disk-Jet Precessing Black Holes: The Case of ASKAP J1832-0911

Abstract

Aims: In this work we investigate whether the 2 min bursts every 44 min from ASKAP J1832-0911 can be explained by Lense-Thirring precession of an intermediate-mass black hole (IMBH) accretion disk launching a Blandford-Znajek jet, as an alternative to magnetar or white-dwarf models. Methods: We derive the Lense-Thirring period P LT=π G Ma c3r3 and solve P LT=44 min for black-hole mass M and dimensionless radius r=R/Rg. We estimate the equipartition field B at r, compute the Blandford-Znajek power P BZ, and the power expected from a gap at the black hole magnetosphere, and compare the resulting jet luminosity to the observed radio and X-ray fluxes at D≈4.5 kpc. We also evaluate expected high-frequency variability and the angular size for Very Long Baseline Interferometry (VLBI) observations. Results: For a0.3\!-\!0.9, an IMBH with M103\!-\!105\,M yields r10\!-\!40\,Rg and P LT=44 min. Equipartition gives B105 G at r, leading to P BZ1035\!-\!39 erg s-1. With radiative efficiency εj10-2\!-\!10-1, the predicted L jet1034\!-\!36 erg s-1 matches the observed FX10-12 erg cm-2 s-1 and radio flux, variability on 100 s could be a smoking gun of this model. Conclusions:The IMBH precessing-jet model simultaneously explains the periodicity, energetics, and duty cycle of ASKAP J1832-0911. Only high-time-resolution X-ray timing (to check pulsations) and multi-frequency radio polarimetry can definitively distinguish it from magnetar or white-dwarf scenarios.