UCB: 3 New Planets and Hints of Planetary Systems Discovered

August 7, 2000
EMBARGOED FOR RELEASE UNTIL 7:30 A.M. BRITISH SUMMER TIME (BST), MONDAY, AUGUST 7, 2000--TO COINCIDE WITH PRESENTATION AT MEETING OF INTERNATIONAL ASTRONOMICAL UNION

Contact: Robert Sanders, UCB Public Information Office
510-643-6998, rls@pa.urel.berkeley.edu

MANCHESTER, ENGLAND--As they add another three to the list of 41 known planets outside our solar system, a team of astronomers based at the University of California at Berkeley, is beginning to see patterns, including hints that many extrasolar planets may have siblings.

To date, only one Sun-like star has been found with multiple planets: Upsilon Andromedae, around which the same team discovered three planets last year. However, Debra A. Fischer, a post-doctoral fellow at UC Berkeley, looked more closely at data for 12 stars her team has been observing long enough to betray the existence of long-period planets, if any, and around which they had already discovered one planet. She found that five--nearly 50 percent--exhibit unexplained wobbles that could result from the tug of a companion, whether another planet, an unseen star or something in between.

“This is the first time anyone has noticed that such a high percentage of stars with one known planet show evidence of a second companion,” Fischer said. All five planets with a possible second planetary companion are large gas giants very near their central star, so close that most astronomers think such planets must have formed farther out and later migrated inward.

“It’s important to know if there are other companions out there,” Fischer said, “because anything else in the system will affect the dynamics and theories of how the planets moved in and parked in their current orbits.”

The analysis, plus data on the three new extrasolar planets, will be presented Aug. 7 by team leaders Geoffrey Marcy, professor of astronomy at UC Berkeley, and Paul Butler, an astronomer at the Carnegie Institution of Washington, at the International Astronomical Union meeting in Manchester, England. A paper describing the results by Fischer, Marcy, Butler and their colleagues will appear soon in the Astrophysical Journal.

The three new planets discovered around the stars HD12661, D 92788 and HD 38529 are large gas giants similar to the planet Jupiter. All are in highly eccentric orbits that alternately bring them close to the planet and carry them far away. This dance alternately drags the star toward and away from Earth by a distance about half the radius of the star, causing a Doppler shift in the star’s light that astronomers can detect.

Specific details about the new planets and their host stars are given below:

The star HD12661 is located at a distance of 121 light years, on the border of the constellation Aries near Triangulum. Its period is 250 days, with an average distance from its star of 0.80 AU. (One astronomical unit, or AU, is 93 million miles, the distance from the Earth to the Sun.) The lower limit on its mass is 2.8 Jupiter masses.

The star HD 92788 is located 104 light years from Earth in the constellation Sextans. Its period is 341.7 days, and it orbits at an average distance of 0.98 AU. Its mass is at least 3.7 Jupiter masses.

The star HD 38529 is 137 light years away, in the constellation Orion. Its period is 14.3 days; its average distance from the star is 0.13 AU. The lower limit on its mass is 0.77 Jupiter masses.

One of the stars, HD 38529, has a planet that whips around in 14.3 days. This planet alone cannot explain the observed wobble in the star, however, leading Fisher and her colleagues to speculate that it has a second companion at a much greater distance from the star.

“We see indication of a second companion, but we can’t be sure because we only see a portion of the orbit,” Fischer said. “The companion could be a dim star, a brown dwarf or another planet.” Brown dwarfs are failed stars--large objects just shy of the mass necessary to sustain hydrogen burning in their core.

More data on another star, 55 Cancri, around which the team found a planet in 1996, indicates it may have a second companion too, Fischer noted. Such a planet, if real, would be at least 3-4 solar masses and have a period of 4,715 days--about 13 Earth years--in a highly eccentric orbit at an average distance of 5.5 AU, similar to Jupiter’s orbit around our Sun.

“This is still speculative,” she cautioned. Still, it led her to look more closely at the dozen stars with known planets for which her team had at least two years of data, enough to show evidence of a second, more distant companion orbiting with a long period.

Five of these planets turned out to have “residual velocities” that could not be explained by a single planet, suggesting the presence of a second companion. The team must collect data for a complete orbit before concluding that another companion exists.

The authors noted that detecting a second companion requires an accurate knowledge of the wobbles caused by the already known planet, which is possible only when that planet is near the star and has a short period. Thus, stars with more distant planets might well have other companions that would not be detectable using the Doppler method.

Interestingly, all three of the new stars are rich in the heaviest atoms, like iron, meaning the stars were formed from dust that had already been cycled through at least one other star. This continues a trend of high metallicity among stars with known planets.

Marcy, Butler, Fischer and their colleagues are monitoring about 900 stars in the northern sky using the University of California’s Lick Observatory in California and the Keck Observatories in Hawaii, plus another 200 in the southern sky with the Anglo-Australian Telescope. They look for wobbles that indicate a planet may be circling the distant sun. To date they have discovered 30 extrasolar planets, including the three reported today. In all, there are now 44 known stars with planets or planetary systems, excluding our own.

“We’re now at a stage where we are finding planets faster than we can investigate them and write up the results,” Marcy said. “It’s wonderful. Planet-hunting has morphed from the marvelous to the mundane.”

The data are feeding other projects, too, including a test of adaptive optics at the Keck Telescopes. With adaptive optics, astronomers could potentially see larger planets around nearby stars. Such observations underway now could set upper limits on the masses of the planets, whereas Doppler observations set only a lower limit for the mass.

This work was funded by the National Aeronautics and Space Administration, the National Science Foundation and by Sun Microsystems.



Editor’s Notes:

Debra Fischer can be reached at 510-643-8973 or via email at fischer@serpens.berkeley.edu. During the week of Aug. 6 she will be at the Nassau Hilton, 231-333-9300.

Geoff Marcy and Paul Butler will be in England at the IAU meeting. Before and after the meeting they can be reached at: Geoff Marcy, gmarcy@etoile.berkeley.edu, 510-642-1952 Paul Butler, paul@dtm.ciw.edu, 202-686-4370 x4401

Complete information on extrasolar planets can be found at the team’s Web site, http://www.exoplanets.org/.

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