The Most Luminous Known Fast Blue Optical Transient AT 2024wpp: Unprecedented Evolution and Properties in the X-rays and Radio

Abstract

We present X-ray (0.3--79 keV) and radio (0.25--203 GHz) observations of the most luminous Fast Blue Optical Transient (LFBOT) AT\,2024wpp at z=0.0868, spanning 2--280 days after first light. AT 2024wpp shows luminous (L X ≈ 1.5 × 1043\, erg\,s-1), variable X-ray emission with a Compton hump peaking at δ t ≈ 50 days. The X-ray spectrum evolves from a soft (F -0.6) to an extremely hard state (F 1.26) accompanied by a re-brightening at δ t ≈ 50\,days. The X-ray emission properties favor an embedded high-energy source shining through asymmetric expanding ejecta. We detect radio emission peaking at L 9\,GHz ≈ 1.7 × 1029\, erg\,s-1\,Hz-1 at δ t ≈ 73 days. The spectral evolution is unprecedented: the early millimeter fluxes rise nearly an order of magnitude during δ t ≈ 17-32 days followed by a decline in spectral peak fluxes. We model the radio emission as synchrotron radiation from an expanding blast wave interacting with a dense environment (M 10-3\, M\,yr-1 for v w = 1000\, km\,s-1). The inferred outflow velocities increase from β c ≈ 0.07\, to\,0.42c during δ t ≈ 32-73 days, indicating an accelerating blast-wave. We interpret these observations as a shock propagating through a dense shell of radius ≈ 1016\,cm, then accelerating into a steep density profile CSM(r) r-3.1. All radio-bright LFBOTs exhibit similar circumstellar medium (CSM) density profiles ( CSM r-3), suggesting similar progenitor processes. The X-ray and radio properties favor a progenitor involving super-Eddington accretion onto a compact object launching mildly-relativistic disk-wind outflows.