Evolution of X-ray Activity in <25 Myr Old Pre-Main Sequence Stars

TL;DR

This study tracks X-ray activity in stars aged 7-25 million years, revealing how magnetic dynamo processes weaken over time and impact planetary atmospheres, with implications for habitability.

Contribution

It provides the first detailed mass-stratified X-ray activity evolution relations for stars aged 7-25 Myr, extending understanding of magnetic dynamo changes during early stellar evolution.

Findings

X-ray luminosity remains constant in early Myr due to extended coronas.

X-ray emission decays more rapidly with increasing stellar mass.

High X-ray flux can strip atmospheres of young planets within a few million years.

Abstract

Measuring the evolution of X-ray emission from pre-main sequence (PMS) stars gives insight into two issues: the response of magnetic dynamo processes to changes in interior structure and the effects of high-energy radiation on protoplanetary disks and primordial planetary atmospheres. We present a sample of 6,003 stars with ages 7-25Myr in ten nearby open clusters from Chandra X-ray and Gaia-EDR3 surveys. Combined with previous results in large samples of younger (<5Myr) stars in MYStIX and SFiNCs star forming regions, mass-stratified activity-age relations are derived for early phases of stellar evolution. X-ray luminosity (Lx) is constant during the first few Myr, possibly due to the presence of extended X-ray coronas insensitive to temporal changes in stellar size. Lx then decays during the 7-25Myr period, more rapidly as stellar mass increases. This decay is interpreted as decreasing efficiency of the alpha^2 dynamo as radiative cores grow and a solar-type alpha-Omega dynamo emerges. For more massive 3.5-7Mo fully radiative stars, the X-ray emission plummets indicating lack of an effective magnetic dynamo. The findings provide improved measurements of high energy radiation effects on circumstellar material, first the protoplanetary disk and then the atmospheres of young planets. The observed X-ray luminosities can be so high that an inner Earth-mass rocky, unmagnetized planet around a solar-mass PMS star might lose its primary and secondary atmospheres within a few-several million years. PMS X-ray emission may thus have a significant impact on evolution of early planetary atmospheres and the conditions promoting the rise of habitability.