Trumpler 3 and NGC 2353 (Labeled).
X-ray: NASA/CXC/Penn State Univ/K. Getman; Optical/IR:
PanSTARRS; Image Processing: NASA/CXC/SAO/N. Wolk
Scientists have found that young stellar
cousins of our Sun are calming down and dimming more quickly in their X-ray
output than previously thought, according to a new study using NASA’s Chandra
X-ray Observatory. A paper describing the results published Monday in The
Astrophysical Journal.
Unlike in the new movie “Project Hail Mary,” this quieting of young stars is a benefit for the prospects for
life on orbiting planets around these stars — not a threat.
Astronomers used Chandra and other
telescopes to monitor how powerful radiation from young stars — often in the
form of dangerous X-rays — can pummel planets surrounding them. They did not
know, however, how long this high-energy barrage continued.
This latest study looked at eight
clusters of stars between the ages of 45 million and 750 million years old. The
researchers found that Sun-like stars in these clusters unleashed only about a
quarter to a third of the X-rays they expected.
"While science fiction – like the
microbes in Project Hail Mary – imagines alien life that dims stellar output by
consuming its energy, our real observations reveal a natural ‘quieting’ of
young Sun-like stars in X-rays,” said Konstantin Getman, the lead author of the
new study from Penn State University. “This is not because an outside force is
consuming their light, but because their internal generation of magnetic fields
becomes less efficient.”
In fact, this calming could be a boon to
the formation of life on planets around stars that are younger versions of our
own Sun. (Our Sun is about 4.6 billion years old, so significantly older than
the stellar cousins in this study.) This is because large amounts of X-rays can
erode a planet’s atmosphere and prevent formation of molecules necessary for
organic life as we know it. On average, three-million-year-old stars with a
mass equal to the Sun produce about a thousand times more X-rays than today's
Sun. Meanwhile, 100-million-year-old solar-mass stars are about 40 times
brighter in X-rays than the present Sun.
Illustration of a young Sun-like star eroding some of
the atmosphere of an orbiting planet.
NASA/SAO/CXC/M. Weiss
“It’s possible that we owe our existence
to our Sun doing the same thing, several billion years ago, that we see these
young stars doing now,” said co-author Vladimir Airapetian of NASA’s Goddard
Space Flight Center in Greenbelt, Maryland. “This real-world dimming echoes the
dramatic stellar change in fiction, but it may be even more fascinating because
it highlights our own Sun's actual history.”
The researchers found that stars with
about the same mass as the Sun quieted down relatively rapidly — after a few
hundred million years — while ones with less mass kept up their high levels of
X-ray emission for longer. Combined with a decrease in the energy of the X-rays
and the disappearance of energetic particles, the Sun-sized stars are
apparently better suited to host planets with robust atmospheres and possibly
blossoming life than previously thought.
The research team also used data from
ESA’s (European Space Agency’s) Gaia satellite and X-ray data from the ROSAT
(ROentgen SATellite) mission. This data allowed them to identify the stars that
were members of the clusters (not foreground or background stars). To measure
the X-ray output from the stars, they made new Chandra observations of five
clusters with ages between 45 million and 100 million years, in addition to
using Chandra and ROSAT data from archives to study three older clusters with
ages between 220 and 750 million years.
Astronomers have not been able to study
the X-ray output of stars in this age range well before. Most astronomers have
relied on sparse data and a derived relation that predicts the X-ray emission
young stars should produce based on their ages and rates of spin. Older and
more slowly rotating stars are usually fainter in X-rays, but the team found
that X-ray output drops off about 15 times more rapidly than the derived
relation predicts during this specific adolescent phase.
“We can only see our Sun at this current
snapshot in time, so to really understand its past we must look to other stars
with about the same mass,” said co-author Eric Feigelson, also of Penn State
University. “By studying X-rays from stars that are hundreds of millions of
years old, we have filled in a large gap in our understanding of their
evolution.”
While they are still investigating the
cause of this slower-than-expected activity, scientists think the process that
generates magnetic fields in these stars may become less efficient. This would
lead to the stars becoming quieter in X-rays more quickly, as they age. The
researchers will continue to look at this and other potential causes for the
rapid dimming of young Sun-like stars.
NASA's Marshall Space Flight Center in
Huntsville, Alabama, manages the Chandra program. The Smithsonian Astrophysical
Observatory's Chandra X-ray Center controls science operations from Cambridge,
Massachusetts, and flight operations from Burlington, Massachusetts.
Read more from NASA’s Chandra X-ray Observatory
Learn more about the Chandra X-ray Observatory and its mission here: https://science.nasa.gov/chandra - https://chandra.si.edu
Source: NASA Finds Young Stars Dim in X-rays Surprisingly Quickly - NASA Science
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