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Main Authors: Yu, Jie, Gehan, Charlotte, Hekker, Saskia, Bazot, Michaël, Cameron, Robert H., Gaulme, Patrick, Bedding, Timothy R., Murphy, Simon J., Han, Zhanwen, Ting, Yuan-Sen, Tayar, Jamie, Chen, Yajie, Gizon, Laurent, Nordhaus, Jason, Bi, Shaolan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.19967
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author Yu, Jie
Gehan, Charlotte
Hekker, Saskia
Bazot, Michaël
Cameron, Robert H.
Gaulme, Patrick
Bedding, Timothy R.
Murphy, Simon J.
Han, Zhanwen
Ting, Yuan-Sen
Tayar, Jamie
Chen, Yajie
Gizon, Laurent
Nordhaus, Jason
Bi, Shaolan
author_facet Yu, Jie
Gehan, Charlotte
Hekker, Saskia
Bazot, Michaël
Cameron, Robert H.
Gaulme, Patrick
Bedding, Timothy R.
Murphy, Simon J.
Han, Zhanwen
Ting, Yuan-Sen
Tayar, Jamie
Chen, Yajie
Gizon, Laurent
Nordhaus, Jason
Bi, Shaolan
contents Stellar activity is fundamental to stellar evolution and the formation and habitability of exoplanets. The interaction between convective motions and rotation in cool stars results in a dynamo process that drives magnetic surface activity. In single stars, activity increases with rotation rate until it saturates for stars with rotation periods Prot < 3 - 10 d. However, the mechanism responsible for saturation remains unclear. Observations indicate that red giants in binary systems that are in spin-orbit resonance exhibit stronger chromospheric activity than single stars with similar rotation rates, suggesting that tidal flows can influence surface activity. Here, we investigate the chromospheric activity of main-sequence binary stars to understand the impact of tidal forces on saturation phenomena. For binaries with 0.5 < Prot/d < 1, mainly contact binaries that share a common thermal envelope, we find enhanced activity rather than saturation. This result supports theoretical predictions that a large-scale $α$ - $ω$ dynamo during common-envelope evolution can generate strong magnetic fields. We also observe supersaturation in chromospheric activity, a phenomenon tentatively noted previously in coronal activity, where activity levels fall below saturation and decrease with shorter rotation periods. Our findings emphasise the importance of studying stellar activity in stars with extreme properties compared to the Sun's.
format Preprint
id arxiv_https___arxiv_org_abs_2505_19967
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhanced magnetic activity in rapidly rotating binary stars
Yu, Jie
Gehan, Charlotte
Hekker, Saskia
Bazot, Michaël
Cameron, Robert H.
Gaulme, Patrick
Bedding, Timothy R.
Murphy, Simon J.
Han, Zhanwen
Ting, Yuan-Sen
Tayar, Jamie
Chen, Yajie
Gizon, Laurent
Nordhaus, Jason
Bi, Shaolan
Solar and Stellar Astrophysics
Stellar activity is fundamental to stellar evolution and the formation and habitability of exoplanets. The interaction between convective motions and rotation in cool stars results in a dynamo process that drives magnetic surface activity. In single stars, activity increases with rotation rate until it saturates for stars with rotation periods Prot < 3 - 10 d. However, the mechanism responsible for saturation remains unclear. Observations indicate that red giants in binary systems that are in spin-orbit resonance exhibit stronger chromospheric activity than single stars with similar rotation rates, suggesting that tidal flows can influence surface activity. Here, we investigate the chromospheric activity of main-sequence binary stars to understand the impact of tidal forces on saturation phenomena. For binaries with 0.5 < Prot/d < 1, mainly contact binaries that share a common thermal envelope, we find enhanced activity rather than saturation. This result supports theoretical predictions that a large-scale $α$ - $ω$ dynamo during common-envelope evolution can generate strong magnetic fields. We also observe supersaturation in chromospheric activity, a phenomenon tentatively noted previously in coronal activity, where activity levels fall below saturation and decrease with shorter rotation periods. Our findings emphasise the importance of studying stellar activity in stars with extreme properties compared to the Sun's.
title Enhanced magnetic activity in rapidly rotating binary stars
topic Solar and Stellar Astrophysics
url https://arxiv.org/abs/2505.19967