Like a game of cosmic bumper cars, scientists think the early days of our solar system were a time of violent turmoil, with planetesimals, asteroids, and comets smashing together and pelting the Earth, Moon, and the other inner planets with debris. Now, in a historical milestone, NASA’s Hubble Space Telescope has directly imaged similar catastrophic collisions in a nearby planetary system around another star, Fomalhaut.
“This is certainly the first time I’ve
ever seen a point of light appear out of nowhere in an exoplanetary system,”
said principal investigator Paul Kalas of the University of California,
Berkeley. “It’s absent in all of our previous Hubble images, which means that
we just witnessed a violent collision between two massive objects and a huge
debris cloud unlike anything in our own solar system today. Amazing!"
Just 25 light-years from Earth,
Fomalhaut is one of the brightest stars in the night sky. Located in the
constellation Piscis Austrinus, also known as the Southern Fish, it is more
massive and brighter than the Sun and is encircled by several belts of dusty
debris.
This composite Hubble Space Telescope image shows the
debris ring and dust clouds cs1 and cs2 around the star Fomalhaut. Fomalhaut
itself is masked out to allow the fainter features to be seen. Its location is
marked by the white star.
Image: NASA, ESA, Paul Kalas (UC Berkeley); Image
Processing: Joseph DePasquale (STScI)
In 2008, scientists used Hubble to
discover a candidate planet around Fomalhaut, making it the first stellar
system with a possible planet found using visible light. That object, called
Fomalhaut b, now appears to be a dust cloud masquerading as a planet—the result of colliding
planetesimals. While searching for Fomalhaut b in recent Hubble observations,
scientists were surprised to find a second point of light at a similar location
around the star. They call this object “circumstellar source 2” or “cs2” while
the first object is now known as “cs1.”
Tackling Mysteries of Colliding
Planetesimals
Why astronomers are seeing both of
these debris clouds so physically close to each other is a mystery. If the
collisions between asteroids and planetesimals were random, cs1 and cs2 should
appear by chance at unrelated locations. Yet, they are positioned intriguingly
near each other along the inner portion of Fomalhaut’s outer debris disk.
Another mystery is why scientists
have witnessed these two events within such a short timeframe. “Previous theory
suggested that there should be one collision every 100,000 years, or longer.
Here, in 20 years, we've seen two,” explained Kalas. “If you had a movie of the
last 3,000 years, and it was sped up so that every year was a fraction of a
second, imagine how many flashes you'd see over that time. Fomalhaut’s
planetary system would be sparkling with these collisions.”
Collisions are fundamental to the
evolution of planetary systems, but they are rare and difficult to study.
This artist's concept shows the sequence of events
leading up to the creation of dust cloud cs2 around the star Fomalhaut. In
Panel 1, the star Fomalhaut appears in the top left corner. Two white dots,
located in the bottom right corner, represent the two massive objects in orbit
around Fomalhaut. In Panel 2, the objects approach each other. Panel 3 shows
the violent collision of these two objects. In Panel 4, the resulting dust
cloud cs2 becomes visible and starlight pushes the dust grains away from the star.
Artwork: NASA, ESA, STScI, Ralf Crawford (STScI)
“The exciting aspect of this
observation is that it allows researchers to estimate both the size of the
colliding bodies and how many of them there are in the disk, information which
is almost impossible to get by any other means,” said co-author Mark Wyatt at
the University of Cambridge in England. “Our estimates put the planetesimals
that were destroyed to create cs1 and cs2 at just 37 miles or 60 kilometers
across, and we infer that there are 300 million such objects orbiting in the
Fomalhaut system.”
“The system is a natural laboratory
to probe how planetesimals behave when undergoing collisions, which in turn
tells us about what they are made of and how they formed,” explained Wyatt.
Cautionary Tale
The transient nature of Fomalhaut
cs1 and cs2 poses challenges for future space missions aiming to directly image
exoplanets. Such telescopes may mistake dust clouds like cs1 and cs2 for actual
planets.
“Fomalhaut cs2 looks exactly like
an extrasolar planet reflecting starlight,” said Kalas. “What we learned from
studying cs1 is that a large dust cloud can masquerade as a planet for many
years. This is a cautionary note for future missions that aim to detect
extrasolar planets in reflected light."
Looking to Future
Kalas and his team have been granted Hubble time to monitor cs2 over the next three years. They want to see how it evolves—does it fade, or does it get brighter? Being closer to the dust belt than cs1, the expanding cs2 cloud is more likely to start encountering other material in the belt. This could lead to a sudden avalanche of more dust in the system, which could cause the whole surrounding area to get brighter.
Credit: NASA's Goddard Space Flight Center; Lead Producer: Paul Morris
“We will be tracing cs2 for any changes
in its shape, brightness, and orbit over time,” said Kalas, “It’s possible that
cs2 will start becoming more oval or cometary in shape as the dust grains are
pushed outward by the pressure of starlight.”
The team also will use the NIRCam
(Near-Infrared Camera) instrument on NASA’s James Webb Space Telescope to
observe cs2. Webb’s NIRCam has the ability to provide color information that
can reveal the size of the cloud’s dust grains and their composition. It can
even determine if the cloud contains water ice.
Hubble and Webb are the only
observatories capable of this kind of imaging. While Hubble primarily sees in
visible wavelengths, Webb could view cs2 in the infrared. These different,
complementary wavelengths are needed to provide a broad multi-spectral investigation
and a more complete picture of the mysterious Fomalhaut system and its rapid
evolution.
This research appears in the December 18 issue of Science.
The Hubble Space Telescope has been operating for over three decades and continues to make ground-breaking discoveries that shape our fundamental understanding of the universe. Hubble is a project of international cooperation between NASA and ESA (European Space Agency). NASA's Goddard Space Flight Center in Greenbelt, Maryland, manages the telescope and mission operations. Lockheed Martin Space, based in Denver, also supports mission operations at Goddard. The Space Telescope Science Institute in Baltimore, which is operated by the Association of Universities for Research in Astronomy, conducts Hubble science operations for NASA.
Source: NASA’s Hubble Sees Asteroids Colliding at Nearby Star for First Time - NASA Science
