Shocked jets in CCSNe can power the zoo of fast blue optical transients

TL;DR

This paper proposes that relativistic jets from hydrogen-rich collapsing stars can explain the diverse observational features of fast blue optical transients, including their optical, radio, and X-ray emissions.

Contribution

It introduces a jet-driven model for FBOTs, linking jet-star interactions to observed multiwavelength signals and differentiating from other models.

Findings

Jet-star interactions produce optical emission with a decay of t^{-2.4}.

Radio emission shows a steady rise over a month, then rapid decay.

X-ray emission becomes visible days after collapse, consistent with observations.

Abstract

Evidence is mounting that recent multiwavelength detections of fast blue optical transients (FBOTs) in star-forming galaxies comprise a new class of transients, whose origin is yet to be understood. We show that hydrogen-rich collapsing stars that launch relativistic jets near the central engine can naturally explain the entire set of FBOT observables. The jet-star interaction forms a mildly-relativistic shocked jet (inner cocoon) component, which powers cooling emission that dominates the high velocity optical signal during the first few weeks, with a typical energy of $ \sim 10^{50}-10^{51} $ erg. During this time, the cocoon radial energy distribution implies that the optical lightcurve exhibits a fast decay of $ L \propto t^{-2.4} $. After a few weeks, when the velocity of the emitting shell is $ \sim 0.01 $ c, the cocoon becomes transparent, and the cooling envelope governs the emission. The interaction between the cocoon and the dense circumstellar winds generates synchrotron self-absorbed emission in the radio bands, featuring a steady rise on a month timescale. After a few months the relativistic outflow decelerates, enters the observer's line of sight, and powers the peak of the radio lightcurve, which rapidly decays thereafter. The jet (and the inner cocoon) become optically thin to X-rays $ \sim $ day after the collapse, allowing X-ray photons to diffuse from the central engine that launched the jet to the observer. Cocoon cooling emission is expected at higher volumetric rates than gamma-ray bursts (GRBs) by a factor of a few, similar to FBOTs. We rule out uncollimated outflows, however both GRB jets and failed collimated jets are compatible with all observables.