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Destiny of Hot Jupiters
Download the press release here:
- Complete press
release package (zip)
- Press release in English (doc, pdf)
- Press release in Chinese (doc, pdf)
- Artists impression of WASP-12b (jpg, pdf, png)
Destiny of Hot Jupiters - Press release
The atmosphere of a planet WASP-12b, which orbits a nearby star, is
reported to pull away by the
gravity of its Sun at a
staggering rate of six
billion metric tons per
second. This is the first
time astronomers have
witnessed the ongoing
disruption and death march
of a planet. The discovery
was made by an international
group of astrophysics,
primarily working at the
recently established Kavli
Institute for Astronomy
and Astrophysics (KIAA) at Peking University. The research
findings have been published
in Nature (Li, S. L.,
Miller, N., Lin, D. N. C. &
Fortney, J. J., 2010, Nature
463, 1054-1056).
Until 15 years ago, the only known planets are those in our own Solar system. Today, more than 400 planets have been detected around other stars. Because they are easier to detect, most of the so-called exo-planets are gaseous and have mass comparable to that of Jupiter. Unlike Jupiter and Saturn one in five of these exo-planets are on orbits very close to their host stars. For some of these systems, the planet regularly passes between their Sun and the Earth and undergoes annular eclipses. By accurately measuring how much of the star's light is blocked out, and how long the occultation lasts, it is possible for astronomers to measure planets' size. Astrophysicists then use this information to figure out the internal make up of these planets and construct scenarios on how they may have acquired these properties.
The planet WASP-12b has puzzled astronomers, since it is one of the few planets that is significantly larger than astrophysicists have predicted. The planet's mass is almost 50% larger than that of Jupiter, the most massive planet in our own Solar System. Although theoretical models had predicted that WASP-12b should have about the same size as Jupiter, it turned out to be 80% larger in size (or almost six times larger in volume). Some mechanism therefore has to be responsible for “puffing up” the planet.
WASP-12b revolves around its host star every single day, at a distance 75 times closer than the distance between the Earth and our Sun. The small separation between WASP-12b and its host star makes it among the most intensely heated planets known. Its day-time temperature is more than 2500 degrees centigrade.
On Earth, tidal forces between the Earth and the Moon cause local sea
levels to modestly rise and fall twice a day. WASP-12b, however, is so
close to it's host star, that the gravitational forces are
enormous. The tremendous tidal forces acting on the planet completely
change the shape of the WASP-12b into the shape similar to that of a
rugby or American football.
The continuous deformation of a planet causes friction in the planet's
interior, and produces heat. Prof. Doug Lin, director of the Kavli
Institute for Astronomy and Astrophysics mentions: “This is the first
time there is direct evidence that the internal heating (or “tidal
heating”) is responsible for puffing up the planet to it's current
size”.
The research team at the Kavli
Institute for Astronomy
and Astrophysics at Peking University, have shown that the combination of the strong tidal forces and the puffed-up size of WASP-12b, causes the planet to lose mass to the host star.
The head author of the Nature article, Shulin Li, who carried out the
bulk of the research work as part of her PhD in Beijing, commented:
“WASP-12b is losing it's mass to the host star at a tremendous rate of
six billion metric tons each second. At this rate, the planet WASP-12b
will be completely destroyed by its host star in about ten million
years”. She continues: “This may sound like a long time, but for
astronomers it's nothing. This planet will live less than 500 times
shorter than the current age of the Earth”.
The material that is stripped off WASP-12b does not directly fall onto
the host star. Instead, it forms a disk around the star, and slowly
spirals inwards. A careful analysis of the orbital motion of WASP-12b
suggests circumstantial evidence of the gravitational force of a
second, lower-mass planet in the disk. This planet is most likely a
massive version of the Earth, a so-called super-Earth.
The disk of planetary material and the embedded super-Earth are
detectable with the currently available telescope facilities. Their
properties can be used to further constrain the history and fate of
the mysterious planet WASP-12b.
Author and contact information:
Author list:
The leading author, Shulin Li (lisl.shulin@gmail.com), was a graduate student at the KIAA, and is currently working at the National Astronomical Observatories of China.
Douglas Lin is the Founding director of the Kavli Institute for Astronomy and Astrophysics, Peking University. He and Jonathan Fortney are professors whereas Neil Miller is a graduate student at the Department of Astronomy and Astrophysics, University of California, Santa Cruz.
Figure caption:
The WASP-12 system. The massive gas giant WASP-12b is shown in purple with the transparent region representing its atmosphere. The gas giant planet's orbit is somewhat non-circular. This indicates that there is probably an unseen lower mass planet in the system, shown in brown, that is perturbing the larger planet's orbit. Mass from the gas giant's atmosphere is pulled off and forms a disk around the star, shown in red.
Embargo date:
18:00 London time / 13:00 US Eastern Time on 24 February 2010
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