Saved in:
Bibliographic Details
Main Authors: Yu, Jie, Ting, Yuan-Sen, Casagrande, Luca, Liu, Fan, Wang, Sharon X., Sun, Qinghui, Huber, Daniel, Chen, Boquan, Cordoni, Giacomo, Da Costa, Gary, Huang, Chelsea X., Karakas, Amanda I., Khanna, Shourya, Liu, Junhui, Ness, Melissa K., Nordlander, Thomas, Taylor, John
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.10339
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866929758247321600
author Yu, Jie
Ting, Yuan-Sen
Casagrande, Luca
Liu, Fan
Wang, Sharon X.
Sun, Qinghui
Huber, Daniel
Chen, Boquan
Cordoni, Giacomo
Da Costa, Gary
Huang, Chelsea X.
Karakas, Amanda I.
Khanna, Shourya
Liu, Junhui
Ness, Melissa K.
Nordlander, Thomas
Taylor, John
author_facet Yu, Jie
Ting, Yuan-Sen
Casagrande, Luca
Liu, Fan
Wang, Sharon X.
Sun, Qinghui
Huber, Daniel
Chen, Boquan
Cordoni, Giacomo
Da Costa, Gary
Huang, Chelsea X.
Karakas, Amanda I.
Khanna, Shourya
Liu, Junhui
Ness, Melissa K.
Nordlander, Thomas
Taylor, John
contents Chemical abundance anomalies in twin stars have recently been considered tell-tale signs of interactions between stars and planets. While such signals are prevalent, their nature remains a subject of debate. On one hand, exoplanet formation may induce chemical depletion in host stars by locking up refractory elements. On the other hand, exoplanet engulfment can result in chemical enrichment, both processes potentially producing similar differential signals. In this study, we aim to observationally disentangle these processes by using the Ca II infrared triplet to measure the magnetic activity of 125 co-moving star pairs with high SNR, high-resolution spectra from the Magellan, Keck, and VLT telescopes. We find that co-natal star pairs in which the two stars exhibit significant chemical abundance differences also show differences in their magnetic activity, with stars depleted in refractories being magnetically more active. Furthermore, the strength of this correlation between differential chemical abundances and differential magnetic activity increases with condensation temperature. One possible explanation is that the chemical anomaly signature may be linked to planet formation, wherein refractory elements are locked into planets, and the host stars become more active due to more efficient contraction during the pre-main-sequence phase or star-planet tidal and magnetic interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2503_10339
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle C3PO IV: co-natal stars depleted in refractories are magnetically more active -- possible imprints of planets
Yu, Jie
Ting, Yuan-Sen
Casagrande, Luca
Liu, Fan
Wang, Sharon X.
Sun, Qinghui
Huber, Daniel
Chen, Boquan
Cordoni, Giacomo
Da Costa, Gary
Huang, Chelsea X.
Karakas, Amanda I.
Khanna, Shourya
Liu, Junhui
Ness, Melissa K.
Nordlander, Thomas
Taylor, John
Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
Chemical abundance anomalies in twin stars have recently been considered tell-tale signs of interactions between stars and planets. While such signals are prevalent, their nature remains a subject of debate. On one hand, exoplanet formation may induce chemical depletion in host stars by locking up refractory elements. On the other hand, exoplanet engulfment can result in chemical enrichment, both processes potentially producing similar differential signals. In this study, we aim to observationally disentangle these processes by using the Ca II infrared triplet to measure the magnetic activity of 125 co-moving star pairs with high SNR, high-resolution spectra from the Magellan, Keck, and VLT telescopes. We find that co-natal star pairs in which the two stars exhibit significant chemical abundance differences also show differences in their magnetic activity, with stars depleted in refractories being magnetically more active. Furthermore, the strength of this correlation between differential chemical abundances and differential magnetic activity increases with condensation temperature. One possible explanation is that the chemical anomaly signature may be linked to planet formation, wherein refractory elements are locked into planets, and the host stars become more active due to more efficient contraction during the pre-main-sequence phase or star-planet tidal and magnetic interactions.
title C3PO IV: co-natal stars depleted in refractories are magnetically more active -- possible imprints of planets
topic Earth and Planetary Astrophysics
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2503.10339