New UH research reshaping views on planets that could possibly support life
New research from the University of Hawaiʻi Institute for Astronomy is reshaping views on planets that could support life.
Findings suggest that powerful radiation — some 12 times stronger than previously thought — could seriously impact a planet’s ability to sustain life.
The groundbreaking study highlights the need for more space telescope data to understand the effects.
The study revealed that red dwarf stars can produce stellar flares that carry far-ultraviolet radiation levels much higher than previously thought, suggesting the intense radiation from these flares could significantly impact whether planets around red dwarf stars can be habitable.
Led by current and former astronomers from the Institute for Astronomy, the research was recently published in the Monthly Notices of the Royal Astronomical Society.
“Few stars have been thought to generate enough UV radiation through flares to impact planet habitability,” said astronomer Vera Berger, who undertook the study while in the institute’s Research Experiences for Undergraduates program, an initiative supported by the National Science Foundation. “Our findings show that many more stars may have this capability.”
Berger and her team used archival data from the GALEX space telescope to search for flares among 300,000 nearby stars.
GALEX is a now-decommissioned NASA mission that simultaneously observed most of the sky at near-and far-UV wavelengths from 2003 to 2013. Using new computational techniques, the team mined novel insights from the data.
“Combining modern computer power with gigabytes of decades-old observations allowed us to search for flares on thousands and thousands of nearby stars,” said Michael Tucker, a PhD graduate of the Institute for Astronomy and now a postdoctoral fellow at Ohio State University.
According to researchers, UV radiation from stellar flares can either erode planetary atmospheres, threatening their potential to support life, or contribute to the formation of RNA building blocks, which are essential for the creation of life.
This study challenges existing models of stellar flares and exoplanet habitability, showing that far-UV emission from flares is on average 3 times more energetic than typically assumed, and can reach up to 12 times the expected energy levels.
“A change of three is the same as the difference in UV in the summer from Anchorage, Alaska, to Honolulu, where unprotected skin can get a sunburn in less than 10 minutes,” said Benjamin J. Shappee, an associate astronomer at the Institute for Astronomy who mentored Berger.
The exact cause of this stronger far-UV emission remains unclear.
The team thinks it might be that flare radiation is concentrated at specific wavelengths, indicating the presence of atoms such as carbon and nitrogen.
“This study has changed the picture of the environments around stars less massive than our sun, which emit very little UV light outside of flares,” said Jason Hinkle, a PhD candidate at the institute who co-authored the study.
According to Berger, now a Churchill Scholar at the University of Cambridge, more data from space telescopes is needed to study the UV light from stars, which is crucial for understanding the source of this emission.