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Main Authors: Sato, Yuri, Bhattacharya, Mukul, Carpio, Jose, Capili, Jewel, Murase, Kohta
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.23252
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author Sato, Yuri
Bhattacharya, Mukul
Carpio, Jose
Capili, Jewel
Murase, Kohta
author_facet Sato, Yuri
Bhattacharya, Mukul
Carpio, Jose
Capili, Jewel
Murase, Kohta
contents Tidal disruption events (TDEs) occur when a star is gravitationally disrupted by the tidal field of a supermassive black hole during a close encounter. Radio emission has recently been detected in TDEs and is commonly attributed to synchrotron radiation from both wind and jetted outflows. However, several TDEs exhibit bright radio flares at late times, which cannot be easily explained if the wind is launched promptly after the stellar disruption. In this study, we model the radio light curves of TDEs with delayed radio flares using three scenarios: an instantaneous wind, a delayed wind, and a delayed relativistic jet. We show that the instantaneous wind model struggles to reproduce delayed radio flare events, indicating the necessity of an additional delayed outflow component. In contrast, the delayed wind model provides a consistent explanation for the observed radio phenomenology, successfully reproducing events both with and without delayed radio flares. For some delayed radio flare events (e.g., ASASSN-15oi and AT 2019dsg), both the delayed wind and delayed jet models can reproduce the observed radio light curves. The delayed jet model produces x-ray and optical emission that is detectable at typical TDE distances, in contrast to wind-driven scenarios. This highlights how multiwavelength observations offer an effective means of distinguishing among possible outflow mechanisms.
format Preprint
id arxiv_https___arxiv_org_abs_2512_23252
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Interpreting the diversity of afterglow emission from radio-detected tidal disruption events with instantaneous and delayed outflows
Sato, Yuri
Bhattacharya, Mukul
Carpio, Jose
Capili, Jewel
Murase, Kohta
High Energy Astrophysical Phenomena
Tidal disruption events (TDEs) occur when a star is gravitationally disrupted by the tidal field of a supermassive black hole during a close encounter. Radio emission has recently been detected in TDEs and is commonly attributed to synchrotron radiation from both wind and jetted outflows. However, several TDEs exhibit bright radio flares at late times, which cannot be easily explained if the wind is launched promptly after the stellar disruption. In this study, we model the radio light curves of TDEs with delayed radio flares using three scenarios: an instantaneous wind, a delayed wind, and a delayed relativistic jet. We show that the instantaneous wind model struggles to reproduce delayed radio flare events, indicating the necessity of an additional delayed outflow component. In contrast, the delayed wind model provides a consistent explanation for the observed radio phenomenology, successfully reproducing events both with and without delayed radio flares. For some delayed radio flare events (e.g., ASASSN-15oi and AT 2019dsg), both the delayed wind and delayed jet models can reproduce the observed radio light curves. The delayed jet model produces x-ray and optical emission that is detectable at typical TDE distances, in contrast to wind-driven scenarios. This highlights how multiwavelength observations offer an effective means of distinguishing among possible outflow mechanisms.
title Interpreting the diversity of afterglow emission from radio-detected tidal disruption events with instantaneous and delayed outflows
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2512.23252