NASA’s James Webb Space Telescope is giving us new insight into the far-future of solar systems like our own, as the agency continues to reveal the secrets of the universe and our place in it. Billions of years ago, a Sun-like star nearing the end of its life swelled tremendously in size to become a red giant before ejecting its outer layers, leaving a hot, remnant core known as a white dwarf. As a red giant, the star should have engulfed and destroyed any nearby planets. Yet astronomers have found a Jupiter-sized exoplanet orbiting the white dwarf every 34 hours at a separation of less than 2 million miles (3 million kilometers).
To solve the mystery of how this
exoplanet survived, an international team of astronomers used NASA’s James Webb
Space Telescope to watch the Jupiter-sized exoplanet WD 1856 b transit its host
star, measuring the planet’s temperature and detecting molecules in its
atmosphere. They found the planet is significantly warmer than expected and
determined how it most likely reached its very tight orbit around the white
dwarf star. The results are a window into the future of planets like Jupiter
after the death of the Sun, billions of years into the future.
The results published Wednesday in
the journal Nature.
WD 1856 b was discovered in 2020 by
scientists using NASA’s TESS (Transiting Exoplanet Survey Satellite) and the
retired Spitzer Space Telescope. It orbits the white dwarf WD 1856+534, which
is located about 80 light-years from Earth. “The planet is about the size of
Jupiter, but the white dwarf it orbits is the size of Earth, so the planet is
seven times larger than its star," said lead author Ryan MacDonald of the
University of St. Andrews in the United Kingdom.
WD 1856 b orbits extremely close to
its host star, a distance 50 times closer than Earth orbits the Sun. If WD 1856
b had originally been orbiting at that distance, it would have been obliterated
while the star was a red giant. How did it survive the death of its host star
and end up in its current position?
Image: Exoplanet WD 1856 b
(Artist's Concept)
Exoplanet
WD 1856 b, shown in this artist’s concept, is a gas giant that orbits its star
at a distance 50 times closer than Earth orbits the Sun. Observations by NASA’s
James Webb Space Telescope determined the planet’s temperature and detected
molecules in its atmosphere.
Artwork:
NASA, ESA, CSA, Ralf Crawford (STScI)
How
big, how hot
The new study used Webb to watch the planet passing in front of its
star. This transit yielded unique information about the planet’s mass, which is
between four and eleven times the mass of Jupiter.
The team also was able to determine the planet’s temperature. During the
transit, light from the star was partly blocked, but infrared light was reduced
less than other wavelengths. The difference was infrared light emitted by the
planet from its own heat. The data indicated that the planet has a temperature
of about 260 degrees Fahrenheit (126 degrees Celsius) — significantly hotter
than it would be if its only source of heat was the light from the white dwarf.
This puzzling discovery turned out to be the key fact that proved how the
planet must have reached its current orbit.
Christopher O’Connor of Northwestern University in Illinois, a co-author
on the paper, was responsible for tracing the temperature of the planet back in
time. O’Connor said, “The big question is how WD 1856 b ended up where it is
today, and there are two theories. One is that the planet was swallowed by the
host star as it was dying, and managed to survive on the inside. The other is
that migration took place due to the gravitational effect of other objects in
the system. The white dwarf is part of a triple star system, and the companion
stars could have influenced WD 1856 b’s orbit.”
The researchers realized that there was no source of energy present to
generate that heat today, so it must be residual energy from an earlier time
when the planet was heated. Using models of how sub-stellar objects like WD
1856 b cool down over time, coupled with the new data from Webb, the team was
able to project its temperature back in time and deduce how long ago the
heating must have happened. The timing is key to determining whether the
heating was from being engulfed by the red giant or occurred during an inward
migration
They concluded that the heating most likely happened between 3 and 5.5
billion years after the star became a white dwarf. In this scenario, the planet
was on a wide orbit that kept it safe from the star during its destructive red
giant phase, and only migrated to its present location later on. “As the planet
moved inward, its interactions with the strong gravity of the white dwarf will
have caused it to warm up considerably, and it has been cooling ever since,”
said O’Connor.
Light from the star passing through the planet’s atmosphere also picked
up information about its chemical composition. “We saw the telltale signatures
of small cloud particles and hydrocarbons, most likely methane, which is the
first time we have seen an atmosphere on a planet transiting a dead star,” said
co-author Victoria Boehm of Cornell University. “We recently observed four more
transits of WD 1856 b with Webb to take a deeper look into its atmospheric
chemistry and can’t wait to see the results.”
Image:
Exoplanet WD 1856 b (Transmission Spectrum)
NASA’s
James Webb Space Telescope measured the constituents of exoplanet WD 1856 b as
it passed in front of its star, finding signs of methane. WD 1856 b orbits a
white dwarf star the size of Earth. As a result, the planet blocks more than
half of the star’s light.
Illustration:
NASA, ESA, CSA, Joseph Olmsted (STScI)
Solar
system’s possible future
In approximately five billion years, the Sun will run out of hydrogen
fuel in its core and swell up more than 100 times larger than it is now into a
red giant star. It will then shed its outer layers and end its life as a white
dwarf star. Mercury, Venus, and possibly the Earth will be destroyed by the red
giant. However, the fate of the more distant planets, particularly the gas
giants, is unclear. Finding and studying planets in orbit around the remnants
of Sun-like stars after their death is a means of learning what might happen in
our own solar system in the far future.
“We’re used to looking back in time when we use telescopes, but this is
the first time we have been able to look forward to what might happen to the
outer planets around the remnant of a Sun-like star,” said MacDonald. “It’s
like using a time machine to peer into the distant future of our solar system.”
The James Webb Space Telescope is the world’s premier space science
observatory. Webb is solving mysteries in our solar system, looking beyond to
distant worlds around other stars, and probing the mysterious structures and
origins of our universe and our place in it. Webb is an international program
led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian
Space Agency).
To learn more about Webb, visit: https://science.nasa.gov/webb
Source: NASA’s Webb Studies How Planet Survived Death of its Star - NASA Science


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