Signs of a planet transiting a star outside of the Milky Way galaxy may have been detected. The finding opens up a new window to search for exoplanets at greater distances than ever before.
From:
Center for Astrophysics, Harvard & Smithsonian
October 27, 2021 – The possible
exoplanet candidate is located in the spiral galaxy Messier 51 (M51), also
called the Whirlpool Galaxy because of its distinctive profile.
Exoplanets are defined as planets
outside of our Solar System. Until now, astronomers have found all other known
exoplanets and exoplanet candidates in the Milky Way galaxy, almost all of them
less than about 3,000 light-years from Earth. An exoplanet in M51 would be
about 28 million light-years away, meaning it would be thousands of times
farther away than those in the Milky Way.
"We are trying to open up a whole
new arena for finding other worlds by searching for planet candidates at X-ray
wavelengths, a strategy that makes it possible to discover them in other
galaxies," said Rosanne Di Stefano of the Center for Astrophysics |
Harvard & Smithsonian (CfA) in Cambridge, Massachusetts, who led the study,
which was published in Nature Astronomy.
This new result is based on transits,
events in which the passage of a planet in front of a star blocks some of the star's
light and produces a characteristic dip. Astronomers using both ground-based
and space-based telescopes -- like those on NASA's Kepler and TESS missions --
have searched for dips in optical light, electromagnetic radiation humans can
see, enabling the discovery of thousands of planets.
Di Stefano and colleagues have instead
searched for dips in the brightness of X-rays received from X-ray bright
binaries. These luminous systems typically contain a neutron star or black hole
pulling in gas from a closely orbiting companion star. The material near the
neutron star or black hole becomes superheated and glows in X-rays.
Because the region producing bright
X-rays is small, a planet passing in front of it could block most or all of the
X-rays, making the transit easier to spot because the X-rays can completely
disappear. This could allow exoplanets to be detected at much greater distances
than current optical light transit studies, which must be able to detect tiny
decreases in light because the planet only blocks a tiny fraction of the star.
The team used this method to detect the
exoplanet candidate in a binary system called M51-ULS-1, located in M51. This
binary system contains a black hole or neutron star orbiting a companion star
with a mass about 20 times that of the Sun. The X-ray transit they found using
Chandra data lasted about three hours, during which the X-ray emission
decreased to zero. Based on this and other information, the researchers
estimate the exoplanet candidate in M51-ULS-1 would be roughly the size of
Saturn, and orbit the neutron star or black hole at about twice the distance of
Saturn from the Sun.
While this is a tantalizing study, more
data would be needed to verify the interpretation as an extragalactic
exoplanet. One challenge is that the planet candidate's large orbit means it
would not cross in front of its binary partner again for about 70 years,
thwarting any attempts for a confirming observation for decades.
"Unfortunately to confirm that
we're seeing a planet we would likely have to wait decades to see another
transit," said co-author Nia Imara of the University of California at
Santa Cruz. "And because of the uncertainties about how long it takes to
orbit, we wouldn't know exactly when to look."
Can the dimming have been caused by a
cloud of gas and dust passing in front of the X-ray source? The researchers
consider this to be an unlikely explanation, as the characteristics of the
event observed in M51-ULS-1 are not consistent with the passage of such a
cloud. The model of a planet candidate is, however, consistent with the data.
"We know we are making an exciting
and bold claim so we expect that other astronomers will look at it very
carefully," said co-author Julia Berndtsson of Princeton University in New
Jersey. "We think we have a strong argument, and this process is how
science works."
If a planet exists in this system, it
likely had a tumultuous history and violent past. An exoplanet in the system
would have had to survive a supernova explosion that created the neutron star
or black hole. The future may also be dangerous. At some point the companion
star could also explode as a supernova and blast the planet once again with
extremely high levels of radiation.
Di Stefano and her colleagues looked for
X-ray transits in three galaxies beyond the Milky Way galaxy, using both
Chandra and the European Space Agency's XMM-Newton. Their search covered 55
systems in M51, 64 systems in Messier 101 (the "Pinwheel" galaxy),
and 119 systems in Messier 104 (the "Sombrero" galaxy), resulting in
the single exoplanet candidate described here.
The authors will search the archives of
both Chandra and XMM-Newton for more exoplanet candidates in other galaxies.
Substantial Chandra datasets are available for at least 20 galaxies, including
some like M31 and M33 that are much closer than M51, allowing shorter transits
to be detectable. Another interesting line of research is to search for X-ray
transits in Milky Way X-ray sources to discover new nearby planets in unusual
environments.
The other authors of this Nature
Astronomy paper are Ryan Urquhart (Michigan State University), Roberto Soria
(University of the Chinese Science Academy), Vinay Kashap (CfA), and Theron
Carmichael (CfA). NASA's Marshall Space Flight Center manages the Chandra
program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center
controls science from Cambridge Massachusetts and flight operations from
Burlington, Massachusetts.
https://www.sciencedaily.com/releases/2021/10/211027094914.htm
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