SwRI Researchers Show Giant Kuiper Belt Planetoid Sedna May Have Formed Far Beyond Pluto.BOULDER, Colo. -- Recently, astronomers reported the surprising discovery of a very large diameter Kuiper Belt Kuiper belt: see comet; Kuiper, Gerard Peter. Kuiper belt or Edgeworth-Kuiper belt Disk-shaped belt of billions of small icy bodies orbiting the Sun beyond the orbit of Neptune, mostly at distances 30–50 times Earth's distance planetoid planetoid: see asteroid. -- (90377) Sedna -- on a distant, 12,500-year-long, eccentric orbit centered approximately 500 astronomical units from the Sun. Sedna's estimated diameter is about 1,600 km, two-thirds that of Pluto. Initial studies of Sedna's origin have speculated that it might have been ejected from the giant planets region of our solar system solar system, the sun and the surrounding planets, natural satellites, dwarf planets, asteroids, meteoroids, and comets that are bound by its gravity. The sun is by far the most massive part of the solar system, containing almost 99.9% of the system's total mass. far inside the orbit of Pluto, or perhaps was captured from a passing star's Kuiper Belt. In a report published in the January 2005 issue of The Astronomical Journal The Astronomical Journal is a monthly scientific journal published by the University of Chicago Press on behalf of the American Astronomical Society. It is one of the premier journals for astronomy in the world. , planetary scientist Dr. Alan Stern S. Alan Stern is the Associate Administrator of NASA's Science Mission Directorate. Formerly a scientist at the Southwest Research Institute, he remains the Principal Investigator of the New Horizons mission to Pluto. of the Space Science and Engineering Division at Southwest Research Institute Southwest Research Institute (SwRI), headquartered in San Antonio, Texas, is one of the oldest and largest independent, nonprofit, applied research and development (R&D) organizations in the United States. Founded in 1947 by Thomas Slick, Jr. (R) (SwRI(R)) shows Sedna could have formed far beyond the distance of Pluto. "If this is actually what happened," Stern points out, "it would indicate that our solar system's planet factory operated across a much larger region than previously thought." It would also indicate that the mysterious Kuiper Belt "edge" near 50 AU (one AU is the distance from the Earth to the Sun) is not an outer edge, but simply the inner edge of an annular annular /an·nu·lar/ (an´u-ler) ring-shaped. an·nu·lar adj. Shaped like or forming a ring. annular ring-shaped. trough, or gap, that is carved out of a much broader structure that has been called the "Kuiper disk." The new Sedna formation study used a planetary accretion code developed by Stern with funding from NASA's Origins of Solar System's Program in the late 1990s for studies of the formation of Kuiper Belt Objects. This software was used to explore the feasibility of building Sedna from boulder-sized and other small bodies at distances between 75 AU (Sedna's closest solar approach distance) and 500 AU (Sedna's average distance from the Sun). Stern's Sedna formation simulations assumed that Sedna's original orbit, while distant from the Sun, was circular. Astronomers agree that Sedna could not have formed in its present, eccentric orbit because such an orbit allows only violent collisions that prevent the growth of small bodies. Stern's simulations further assumed that the solar nebula solar nebula Gaseous cloud from which, in the nebular hypothesis of the origin of the solar system, the Sun and planets formed by condensation. In 1755 Immanuel Kant suggested that a nebula gradually pulled together by its own gravity developed into the Sun and planets. -- the disk of material out of which the planets formed -- was much more extended than most previous simulations had assumed. "The Sedna formation simulations assumed that the primordial solar nebula was a disk about the size of those observed around many nearby middle-aged stars -- like the well-known example of the 1,500-AU-wide disk around the star Beta Pictoris Beta Pictoris (β Pic / β Pictoris) is the second brightest star in the constellation Pictor. The β Pic system is very young, only 8-20 million years old[1] although it is already on the main sequence. ," Stern says. "The model calculations found that objects as large, or even larger, than Sedna could easily form in circular orbits at distances of 75 to 500 AU, and that their formation time could have been fairly short -- just a few percent the age of the solar system," Stern continues. "If Sedna did form this far out, it is likely to be accompanied by a cohort of other large planetoids in this very distant region of the solar system. One telltale sign that these objects were formed where they are, rather than in another location, would be if a good fraction of them are on near circular orbits." Editors: An image to accompany this story is available at http://www.swri.org/press/sedna.htm SwRI is an independent, nonprofit, applied research and development organization based in San Antonio, with more than 2,800 employees and an annual research volume of more than $355 million. |
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