The kangaroo’s first hop: the early fast cooling phase of EP250108a/SN 2025kg

The kangaroo’s first hop: the early fast cooling phase of EP250108a/SN 2025kg
Rob A. J. Eyles-Ferris, Peter G. Jonker, Andrew J. Levan, Daniele Bj{o}rn Malesani, Nikhil Sarin, Christopher L. Fryer, Jillian C. Rastinejad, Eric Burns, Nial R. Tanvir, Paul T. O’Brien, Wen-fai Fong, Ilya Mandel, Benjamin P. Gompertz, Charles D. Kilpatrick, Steven Bloemen, Joe S. Bright, Francesco Carotenuto, Gregory Corcoran, Laura Cotter, Paul J. Groot, Luca Izzo, Tanmoy Laskar, Antonio Martin-Carrillo, Jesse Palmerio, Maria E. Ravasio, Jan van Roestel, Andrea Saccardi, Rhaana L. C. Starling, Aishwarya Linesh Thakur, Susanna D. Vergani, Paul M. Vreeswijk, Franz E. Bauer, Sergio Campana, Jennifer A. Chac’on, Ashley A. Chrimes, Stefano Covino, Joyce N. D. van Dalen, Valerio D’Elia, Massimiliano De Pasquale, Nusrin Habeeb, Dieter H. Hartmann, Agnes P. C. van Hoof, P’all Jakobsson, Yashaswi Julakanti, Giorgos Leloudas, Daniel Mata S’anchez, Christopher J. Nixon, Dani"elle L. A. Pieterse, Giavanna Pugliese, Jonathan Quirola-V’asquez, Ben C. Rayson, Ruben Salvaterra, Ben Schneider, Manuel A. P. Torres, Tayyaba Zafar
arXiv:2504.08886v3 Announce Type: replace
Abstract: Fast X-ray transients (FXTs) are a rare and poorly understood population of events. Previously difficult to detect in real time, the launch of the Einstein Probe with its wide field X-ray telescope has led to a rapid expansion in the sample and allowed the exploration of these transients across the electromagnetic spectrum. EP250108a is a recently detected example linked to an optical counterpart, SN 2025kg, or ‘the kangaroo’. Together with a companion paper (Rastinejad et al. 2025), we present our observing campaign and analysis of this event. In this letter, we focus on the early evolution of the optical counterpart over the first six days, including our measurement of the redshift of $z=0.17641$. We find that the source is well-modelled by a rapidly expanding cooling blackbody. We show the observed X-ray and radio properties are consistent with a collapsar-powered jet that is low energy ($lesssim10^{51}$ erg) and/or fails to break out of the dense material surrounding it. The optical emission therefore likely arises from a shocked cocoon resulting from the trapped jet; however, we also examine the possibility that it emerges from the shock produced as the supernova ejecta expand into a dense shell of circumstellar material. We compare to other supernovae and fast transients showing similar features, finding significant similarities with SN 2006aj and SN 2020bvc. This suggests trapped jets could be more common than previously thought and SN 2025kg may herald a larger sample of similar transients.arXiv:2504.08886v3 Announce Type: replace
Abstract: Fast X-ray transients (FXTs) are a rare and poorly understood population of events. Previously difficult to detect in real time, the launch of the Einstein Probe with its wide field X-ray telescope has led to a rapid expansion in the sample and allowed the exploration of these transients across the electromagnetic spectrum. EP250108a is a recently detected example linked to an optical counterpart, SN 2025kg, or ‘the kangaroo’. Together with a companion paper (Rastinejad et al. 2025), we present our observing campaign and analysis of this event. In this letter, we focus on the early evolution of the optical counterpart over the first six days, including our measurement of the redshift of $z=0.17641$. We find that the source is well-modelled by a rapidly expanding cooling blackbody. We show the observed X-ray and radio properties are consistent with a collapsar-powered jet that is low energy ($lesssim10^{51}$ erg) and/or fails to break out of the dense material surrounding it. The optical emission therefore likely arises from a shocked cocoon resulting from the trapped jet; however, we also examine the possibility that it emerges from the shock produced as the supernova ejecta expand into a dense shell of circumstellar material. We compare to other supernovae and fast transients showing similar features, finding significant similarities with SN 2006aj and SN 2020bvc. This suggests trapped jets could be more common than previously thought and SN 2025kg may herald a larger sample of similar transients.