VVV-WIT-13: an eruptive young star with cool molecular features

Zhen Guo; Philip Lucas; Sergey N. Yurchenko; Tomasz Kaminski; Matias Montesinos; Sergei Nayakshin; Vardan Elbakyan; Javier Osses; Alessio Caratti o Garatti; He Zhao; Radostin Kurtev; Jura Borissova; Calum Morris; Dante Minniti; Javier Alonso-García; Vitor Fermiano; Roberto K. Saito; Niall Miller; Gabriella Zsidi; H. D. S. Muthu; Cesar Briceño; Carlos Contreras Peña; A. E. Lynas-Gray; Jonathan Tennyson; Lingzhi Wang; Lixin Yu; Diego Benitez-Palacios; Jinyi Yang; Michael Kuhn; Sharon X. Wang

VVV-WIT-13: an eruptive young star with cool molecular features

Zhen Guo, Philip Lucas, Sergey N. Yurchenko, Tomasz Kaminski, Matias Montesinos, Sergei Nayakshin, Vardan Elbakyan, Javier Osses, Alessio Caratti o Garatti, He Zhao, Radostin Kurtev, Jura Borissova, Calum Morris, Dante Minniti, Javier Alonso-García, Vitor Fermiano, Roberto K. Saito, Niall Miller, Gabriella Zsidi, H. D. S. MuthuCesar Briceño, Carlos Contreras Peña, A. E. Lynas-Gray, Jonathan Tennyson, Lingzhi Wang, Lixin Yu, Diego Benitez-Palacios, Jinyi Yang, Michael Kuhn, Sharon X. Wang

Research output: Contribution to journal › Article › peer-review

Abstract

Here we investigate an infrared eruptive source, identified from the decade-long VISTA Variables in the Via Lactea survey (VVV). We named this target after a group of variable sources discovered by VVV, as VVV-WIT-13, with WIT standing for "What Is This?", due to its unique photometric variation behaviour and the mysterious origin of the outburst. This target exhibited an outburst with a 5.7 mag amplitude in the Ks-band, remained on its brightness plateau for 3.5 years, and then rapidly faded to its pre-eruptive brightness afterwards. We aim to reveal the variable nature and outburst origin of VVV-WIT-13 by presenting our follow-up photometric and spectroscopic observations along with theoretical models. We gathered photometric time series in both near- and mid-infrared wavelengths. We obtained near-infrared spectra during the outburst and decaying stages on XSHOOTER/VLT and FIRE/Magellan, and then fitted the detected molecular absorption features using models from ExoMol. We applied 2D numerical simulations to re-create the observables of the eruptive phenomenon. We observe deep AlO absorption bands in the infrared spectra of VVV-WIT-13, during the outburst stage, along with other more common absorption bands (e.g. CO). Our best-fit model suggests a 600 K temperature of the AlO absorption band. In the decaying stage, the AlO bands disappeared, whilst broad blue-shifted H2 lines arose, a common indicator of stellar wind and outflow. The observational evidence suggests that the CO and TiO features originate from an outflow or a wind environment. We find that VVV-WIT-13 is an eruptive young star with instability occurring in the accretion disk. One favoured theoretical explanation of this event is a disrupted gas clump at a distance of 3 au from the source. If confirmed, this would be the first such event observed in real time.

Original language	English
Number of pages	16
Journal	Astronomy & Astrophysics
Publication status	Accepted/In press - 18 Sept 2025

Keywords

astro-ph.SR

Embargoed Document

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Accepted author manuscript, 2.62 MB
Licence: Unspecified

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Guo, Z., Lucas, P., Yurchenko, S. N., Kaminski, T., Montesinos, M., Nayakshin, S., Elbakyan, V., Osses, J., Garatti, A. C. O., Zhao, H., Kurtev, R., Borissova, J., Morris, C., Minniti, D., Alonso-García, J., Fermiano, V., Saito, R. K., Miller, N., Zsidi, G., ... Wang, S. X. (Accepted/In press). VVV-WIT-13: an eruptive young star with cool molecular features. Astronomy & Astrophysics.

@article{0a17556ea7f14e7aba4f8e9ebaa386e5,

title = "VVV-WIT-13: an eruptive young star with cool molecular features",

abstract = "Here we investigate an infrared eruptive source, identified from the decade-long VISTA Variables in the Via Lactea survey (VVV). We named this target after a group of variable sources discovered by VVV, as VVV-WIT-13, with WIT standing for {"}What Is This?{"}, due to its unique photometric variation behaviour and the mysterious origin of the outburst. This target exhibited an outburst with a 5.7 mag amplitude in the Ks-band, remained on its brightness plateau for 3.5 years, and then rapidly faded to its pre-eruptive brightness afterwards. We aim to reveal the variable nature and outburst origin of VVV-WIT-13 by presenting our follow-up photometric and spectroscopic observations along with theoretical models. We gathered photometric time series in both near- and mid-infrared wavelengths. We obtained near-infrared spectra during the outburst and decaying stages on XSHOOTER/VLT and FIRE/Magellan, and then fitted the detected molecular absorption features using models from ExoMol. We applied 2D numerical simulations to re-create the observables of the eruptive phenomenon. We observe deep AlO absorption bands in the infrared spectra of VVV-WIT-13, during the outburst stage, along with other more common absorption bands (e.g. CO). Our best-fit model suggests a 600 K temperature of the AlO absorption band. In the decaying stage, the AlO bands disappeared, whilst broad blue-shifted H2 lines arose, a common indicator of stellar wind and outflow. The observational evidence suggests that the CO and TiO features originate from an outflow or a wind environment. We find that VVV-WIT-13 is an eruptive young star with instability occurring in the accretion disk. One favoured theoretical explanation of this event is a disrupted gas clump at a distance of 3 au from the source. If confirmed, this would be the first such event observed in real time.",

keywords = "astro-ph.SR",

author = "Zhen Guo and Philip Lucas and Yurchenko, \{Sergey N.\} and Tomasz Kaminski and Matias Montesinos and Sergei Nayakshin and Vardan Elbakyan and Javier Osses and Garatti, \{Alessio Caratti o\} and He Zhao and Radostin Kurtev and Jura Borissova and Calum Morris and Dante Minniti and Javier Alonso-Garc{\'i}a and Vitor Fermiano and Saito, \{Roberto K.\} and Niall Miller and Gabriella Zsidi and Muthu, \{H. D. S.\} and Cesar Brice{\~n}o and Pe{\~n}a, \{Carlos Contreras\} and Lynas-Gray, \{A. E.\} and Jonathan Tennyson and Lingzhi Wang and Lixin Yu and Diego Benitez-Palacios and Jinyi Yang and Michael Kuhn and Wang, \{Sharon X.\}",

year = "2025",

month = sep,

day = "18",

language = "English",

journal = "Astronomy \& Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Guo, Z, Lucas, P, Yurchenko, SN, Kaminski, T, Montesinos, M, Nayakshin, S, Elbakyan, V, Osses, J, Garatti, ACO, Zhao, H, Kurtev, R, Borissova, J, Morris, C, Minniti, D, Alonso-García, J, Fermiano, V, Saito, RK, Miller, N, Zsidi, G, Muthu, HDS, Briceño, C, Peña, CC, Lynas-Gray, AE, Tennyson, J, Wang, L, Yu, L, Benitez-Palacios, D, Yang, J, Kuhn, M & Wang, SX 2025, 'VVV-WIT-13: an eruptive young star with cool molecular features', Astronomy & Astrophysics.

TY - JOUR

T1 - VVV-WIT-13: an eruptive young star with cool molecular features

AU - Guo, Zhen

AU - Lucas, Philip

AU - Yurchenko, Sergey N.

AU - Kaminski, Tomasz

AU - Montesinos, Matias

AU - Nayakshin, Sergei

AU - Elbakyan, Vardan

AU - Osses, Javier

AU - Garatti, Alessio Caratti o

AU - Zhao, He

AU - Kurtev, Radostin

AU - Borissova, Jura

AU - Morris, Calum

AU - Minniti, Dante

AU - Alonso-García, Javier

AU - Fermiano, Vitor

AU - Saito, Roberto K.

AU - Miller, Niall

AU - Zsidi, Gabriella

AU - Muthu, H. D. S.

AU - Briceño, Cesar

AU - Peña, Carlos Contreras

AU - Lynas-Gray, A. E.

AU - Tennyson, Jonathan

AU - Wang, Lingzhi

AU - Yu, Lixin

AU - Benitez-Palacios, Diego

AU - Yang, Jinyi

AU - Kuhn, Michael

AU - Wang, Sharon X.

PY - 2025/9/18

Y1 - 2025/9/18

N2 - Here we investigate an infrared eruptive source, identified from the decade-long VISTA Variables in the Via Lactea survey (VVV). We named this target after a group of variable sources discovered by VVV, as VVV-WIT-13, with WIT standing for "What Is This?", due to its unique photometric variation behaviour and the mysterious origin of the outburst. This target exhibited an outburst with a 5.7 mag amplitude in the Ks-band, remained on its brightness plateau for 3.5 years, and then rapidly faded to its pre-eruptive brightness afterwards. We aim to reveal the variable nature and outburst origin of VVV-WIT-13 by presenting our follow-up photometric and spectroscopic observations along with theoretical models. We gathered photometric time series in both near- and mid-infrared wavelengths. We obtained near-infrared spectra during the outburst and decaying stages on XSHOOTER/VLT and FIRE/Magellan, and then fitted the detected molecular absorption features using models from ExoMol. We applied 2D numerical simulations to re-create the observables of the eruptive phenomenon. We observe deep AlO absorption bands in the infrared spectra of VVV-WIT-13, during the outburst stage, along with other more common absorption bands (e.g. CO). Our best-fit model suggests a 600 K temperature of the AlO absorption band. In the decaying stage, the AlO bands disappeared, whilst broad blue-shifted H2 lines arose, a common indicator of stellar wind and outflow. The observational evidence suggests that the CO and TiO features originate from an outflow or a wind environment. We find that VVV-WIT-13 is an eruptive young star with instability occurring in the accretion disk. One favoured theoretical explanation of this event is a disrupted gas clump at a distance of 3 au from the source. If confirmed, this would be the first such event observed in real time.

AB - Here we investigate an infrared eruptive source, identified from the decade-long VISTA Variables in the Via Lactea survey (VVV). We named this target after a group of variable sources discovered by VVV, as VVV-WIT-13, with WIT standing for "What Is This?", due to its unique photometric variation behaviour and the mysterious origin of the outburst. This target exhibited an outburst with a 5.7 mag amplitude in the Ks-band, remained on its brightness plateau for 3.5 years, and then rapidly faded to its pre-eruptive brightness afterwards. We aim to reveal the variable nature and outburst origin of VVV-WIT-13 by presenting our follow-up photometric and spectroscopic observations along with theoretical models. We gathered photometric time series in both near- and mid-infrared wavelengths. We obtained near-infrared spectra during the outburst and decaying stages on XSHOOTER/VLT and FIRE/Magellan, and then fitted the detected molecular absorption features using models from ExoMol. We applied 2D numerical simulations to re-create the observables of the eruptive phenomenon. We observe deep AlO absorption bands in the infrared spectra of VVV-WIT-13, during the outburst stage, along with other more common absorption bands (e.g. CO). Our best-fit model suggests a 600 K temperature of the AlO absorption band. In the decaying stage, the AlO bands disappeared, whilst broad blue-shifted H2 lines arose, a common indicator of stellar wind and outflow. The observational evidence suggests that the CO and TiO features originate from an outflow or a wind environment. We find that VVV-WIT-13 is an eruptive young star with instability occurring in the accretion disk. One favoured theoretical explanation of this event is a disrupted gas clump at a distance of 3 au from the source. If confirmed, this would be the first such event observed in real time.

KW - astro-ph.SR

M3 - Article

SN - 0004-6361

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

ER -

VVV-WIT-13: an eruptive young star with cool molecular features

Abstract

Keywords

Embargoed Document

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