The attempted polarity reversal and evolving magnetic environment of AD Leo

TL;DR

This study investigates the magnetic field evolution of AD Leo, finding no polarity reversal over recent years, and assesses its impact on stellar wind and habitability, revealing a stable, axisymmetric magnetic configuration with significant implications for exoplanet environments.

Contribution

The paper provides the first detailed magnetic field reconstruction of AD Leo over multiple years and models its stellar wind, offering new insights into magnetic stability and habitability around active M dwarfs.

Findings

No polarity reversal observed in AD Leo's magnetic field.

Stellar wind mass loss rates are an order of magnitude higher than the Sun's.

Habitable zone lies beyond the Alfvén surface, with potential for magnetic shielding.

Abstract

In the past two decades, the observed large-scale magnetic field of the active M dwarf star AD Leo has evolved from strongly to mildly negative, raising a suspicion that it might switch polarity. Although magnetic field reversals are observed every 11 years for the Sun, such reversals are poorly understood for M dwarfs. Further, no reversals have been observed for fast-rotating M dwarfs. We examine the properties of AD Leo's large-scale magnetic field and investigate how its evolution affects the space weather environment. We analysed spectropolarimetric data collected by ESPaDOnS and SPIRou in late-2022 and early-2023. With the optical and near-infrared data we computed the longitudinal magnetic field, and with the near-infrared data reconstructed the large-scale magnetic field using Zeeman-Doppler imaging. Using five magnetograms, from 2019 to 2023, we simulated three-dimensional Alfven wave-driven stellar winds using the space weather code SWMF. Although we see an evolution of the large-scale magnetic field of AD Leo, we find no polarity reversal. Rather, we see a restoration of the field to a simpler configuration with consistently negative values for the longitudinal magnetic field strength. Our new large-scale field reconstruction for AD Leo is characterised by a highly axisymmetric, poloidal-dipolar field with an increased mean large-scale field strength. SWMF simulations find the stellar mass loss rates to be, on average, an order of magnitude greater than that of the Sun. Additionally, we find that the habitable zone resides beyond the Alfven surface. Hypothetical magnetised habitable zone planets (with planetary field strengths greater than 0.34 G) would likely be shielded from the incident wind and atmospheric erosion would be negligible. Further, we find variable conditions across each epoch due to the evolving axisymmetry of the stellar large-scale magnetic field.