Starspots as the origin of ultrafast drifting radio bursts from an active M dwarf

Jiale Zhang; Hui Tian; Stefano Bellotti; Tianqi Cang; Joseph R. Callingham; Harish K. Vedantham; Bin Chen; Sijie Yu; Philippe Zarka; Corentin K. Louis; Peng Jiang; Hongpeng Lu; Yang Gao; Jinghai Sun; Hengqian Gan; Hui Li; Chun Sun; Zheng Lei; Menglin Huang

doi:10.1126/sciadv.adw6116

Starspots as the origin of ultrafast drifting radio bursts from an active M dwarf

Jiale Zhang
, Hui Tian
, Stefano Bellotti
, Tianqi Cang
, Joseph R. Callingham
, Harish K. Vedantham
, Bin Chen
, Sijie Yu
, Philippe Zarka
, Corentin K. Louis
, Peng Jiang
, Hongpeng Lu
, Yang Gao
, Jinghai Sun
, Hengqian Gan
, Hui Li
, Chun Sun
, Zheng Lei
, Menglin Huang

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

Abstract

Detecting coherent radio bursts from nearby M dwarfs provides opportunities for exploring their magnetic activity and interaction with orbiting exoplanets. However, it remains uncertain whether the emission is related to flare-like activity similar to the Sun or magnetospheric process akin to magnetized planets. Using observations (1.0 to 1.5 gigahertz) taken by the Five-hundred- meter Aperture Spherical radio Telescope, we found a type of millisecond-scale radio bursts with exceptionally high-frequency drift rates (~8 gigahertz per second) from an active M dwarf, AD Leo. The ultrafast drift rates point to a source region with a notably low magnetic scale height (<0.15 r_⋆, r_⋆ as the stellar radius), a feature not expected in a commonly assumed dipole-like global field but highly possible in localized strong-field structures, i.e., starspots. Our findings suggest that a concentrated magnetic field above starspots could be responsible for some of the most intense radio bursts from M dwarfs, supporting a solar-like electron acceleration mechanism.

Original language	English (US)
Article number	eadw6116
Journal	Science Advances
Volume	11
Issue number	42
DOIs	https://doi.org/10.1126/sciadv.adw6116
State	Published - Oct 17 2025

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10.1126/sciadv.adw6116

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Zhang, J., Tian, H., Bellotti, S., Cang, T., Callingham, J. R., Vedantham, H. K., Chen, B., Yu, S., Zarka, P., Louis, C. K., Jiang, P., Lu, H., Gao, Y., Sun, J., Gan, H., Li, H., Sun, C., Lei, Z., & Huang, M. (2025). Starspots as the origin of ultrafast drifting radio bursts from an active M dwarf. Science Advances, 11(42), Article eadw6116. https://doi.org/10.1126/sciadv.adw6116

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title = "Starspots as the origin of ultrafast drifting radio bursts from an active M dwarf",

abstract = "Detecting coherent radio bursts from nearby M dwarfs provides opportunities for exploring their magnetic activity and interaction with orbiting exoplanets. However, it remains uncertain whether the emission is related to flare-like activity similar to the Sun or magnetospheric process akin to magnetized planets. Using observations (1.0 to 1.5 gigahertz) taken by the Five-hundred- meter Aperture Spherical radio Telescope, we found a type of millisecond-scale radio bursts with exceptionally high-frequency drift rates (\textasciitilde{}8 gigahertz per second) from an active M dwarf, AD Leo. The ultrafast drift rates point to a source region with a notably low magnetic scale height (<0.15 r⋆, r⋆ as the stellar radius), a feature not expected in a commonly assumed dipole-like global field but highly possible in localized strong-field structures, i.e., starspots. Our findings suggest that a concentrated magnetic field above starspots could be responsible for some of the most intense radio bursts from M dwarfs, supporting a solar-like electron acceleration mechanism.",

author = "Jiale Zhang and Hui Tian and Stefano Bellotti and Tianqi Cang and Callingham, \{Joseph R.\} and Vedantham, \{Harish K.\} and Bin Chen and Sijie Yu and Philippe Zarka and Louis, \{Corentin K.\} and Peng Jiang and Hongpeng Lu and Yang Gao and Jinghai Sun and Hengqian Gan and Hui Li and Chun Sun and Zheng Lei and Menglin Huang",

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T1 - Starspots as the origin of ultrafast drifting radio bursts from an active M dwarf

AU - Zhang, Jiale

AU - Tian, Hui

AU - Bellotti, Stefano

AU - Cang, Tianqi

AU - Callingham, Joseph R.

AU - Vedantham, Harish K.

AU - Chen, Bin

AU - Yu, Sijie

AU - Zarka, Philippe

AU - Louis, Corentin K.

AU - Jiang, Peng

AU - Lu, Hongpeng

AU - Gao, Yang

AU - Sun, Jinghai

AU - Gan, Hengqian

AU - Li, Hui

AU - Sun, Chun

AU - Lei, Zheng

AU - Huang, Menglin

N1 - Publisher Copyright: © 2025 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).

PY - 2025/10/17

Y1 - 2025/10/17

N2 - Detecting coherent radio bursts from nearby M dwarfs provides opportunities for exploring their magnetic activity and interaction with orbiting exoplanets. However, it remains uncertain whether the emission is related to flare-like activity similar to the Sun or magnetospheric process akin to magnetized planets. Using observations (1.0 to 1.5 gigahertz) taken by the Five-hundred- meter Aperture Spherical radio Telescope, we found a type of millisecond-scale radio bursts with exceptionally high-frequency drift rates (~8 gigahertz per second) from an active M dwarf, AD Leo. The ultrafast drift rates point to a source region with a notably low magnetic scale height (<0.15 r⋆, r⋆ as the stellar radius), a feature not expected in a commonly assumed dipole-like global field but highly possible in localized strong-field structures, i.e., starspots. Our findings suggest that a concentrated magnetic field above starspots could be responsible for some of the most intense radio bursts from M dwarfs, supporting a solar-like electron acceleration mechanism.

AB - Detecting coherent radio bursts from nearby M dwarfs provides opportunities for exploring their magnetic activity and interaction with orbiting exoplanets. However, it remains uncertain whether the emission is related to flare-like activity similar to the Sun or magnetospheric process akin to magnetized planets. Using observations (1.0 to 1.5 gigahertz) taken by the Five-hundred- meter Aperture Spherical radio Telescope, we found a type of millisecond-scale radio bursts with exceptionally high-frequency drift rates (~8 gigahertz per second) from an active M dwarf, AD Leo. The ultrafast drift rates point to a source region with a notably low magnetic scale height (<0.15 r⋆, r⋆ as the stellar radius), a feature not expected in a commonly assumed dipole-like global field but highly possible in localized strong-field structures, i.e., starspots. Our findings suggest that a concentrated magnetic field above starspots could be responsible for some of the most intense radio bursts from M dwarfs, supporting a solar-like electron acceleration mechanism.

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JF - Science Advances

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ER -

Starspots as the origin of ultrafast drifting radio bursts from an active M dwarf

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