Planet formation on the fast track: growing up in a hurry.It's textbook astronomy. Planets form little by little as material slowly congeals within the disk of gas, dust, and ice known to swaddle swad·dle tr.v. swad·dled, swad·dling, swad·dles 1. To wrap or bind in bandages; swathe. 2. To wrap (a baby) in swaddling clothes. 3. To restrain or restrict. n. young stars. First, gravity gathers together bits of dust, which merge to form boulder-size bodies, which themselves coalesce co·a·lesce intr.v. co·a·lesced, co·a·lesc·ing, co·a·lesc·es 1. To grow together; fuse. 2. To come together so as to form one whole; unite: into bigger and bigger objects. In about a million years, these form rocky planets, like Earth and Mars. Over the next few million years, gas from the disk settles around some of these solid bodies, and they grow far bigger, becoming giants like gaseous Saturn and Jupiter. But several astronomers now say that this model for making planets may not be entirely correct. They've devised an alternative theory in which planets as massive as Jupiter--whether orbiting our sun or a distant star--would form completely within just a few hundred years, rather than the millions mandated by today's most popular planet-formation model. Both models start with the same reservoir of planet-making materials. This spinning cloud of gas, dust, and ice, like tossed pizza dough, rapidly flattens into a disk. Over time, gravity causes material in this so-called protoplanetary disk protoplanetary disk A rotating disk of dust and gas that surrounds the core of a developing solar system. It may eventually develop into orbiting celestial bodies such as planets and asteroids. See more at planetesimal. to clump into planet-size objects. The two models are poles apart, however, when it comes to the speed of this clustering and the size of the initial clumps. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the standard model, known as the core-accretion model, making Jupiter required the initial formation of a solid core 5 to 10 times Earth's mass. That buildup would have taken about a million years. This large core then had enough gravity to attract a massive amount of gas from the protoplanetary disk to create a planet of Jovian proportions. In the accretion model, these so-called gas giants may take as much as 10 million years to form. That's several million years too long, contends Lucio Mayer of the University of Zurich History The University of Zurich was founded in 1833 with existing colleges of theology (founded by Huldrych Zwingli in 1525), law and medicine merged together with a new faculty of Philosophy. in Switzerland. Direct telescope observations suggest that protoplanetary disks don't last more than about 7 million years, and studies of the environment in which stars form suggest that many disks may evaporate in much less time. WAR OF THE WORLD-MAKERS The typical star in the Milky Way Milky Way, the galaxy of which the sun and solar system are a part, seen as a broad band of light arching across the night sky from horizon to horizon; if not blocked by the horizon, it would be seen as a circle around the entire sky. is born into a tough neighborhood, Mayer says. Most stars hatch in dense molecular clouds, which amount to crowded stellar nurseries. The youngsters are extremely hot, and the ultraviolet light Ultraviolet light A portion of the light spectrum not visible to the eye. Two bands of the UV spectrum, UVA and UVB, are used to treat psoriasis and other skin diseases. they blast into space can evaporate a protoplanetary disk in less than 100,000 years. In the accretion model, that's not enough time for a Jupiterlike planet to form. Even if there are no other hot stars around, recent simulations show that when molecular clouds fragment into individual stars, the gravitational grav·i·ta·tion n. 1. Physics a. The natural phenomenon of attraction between physical objects with mass or energy. b. The act or process of moving under the influence of this attraction. 2. tug of war tug of war n. pl. tugs of war 1. Games A contest of strength in which two teams tug on opposite ends of a rope, each trying to pull the other across a dividing line. 2. between neighbors can lop off Verb 1. lop off - remove by or as if by cutting; "cut off the ear"; "lop off the dead branch" chop off, cut off abscise - remove or separate by abscission roach - cut the mane off (a horse) the gaseous, outer parts of protoplanetary disks in 100,000 years or less. "If a gas giant planet can't form quickly, it probably can't form at all," concludes Thomas Quinn of the University of Washington in Seattle. If the core-accretion model is correct, gas giants ought to be rare, Quinn argues. Yet since 1995, astronomers have found more than 100 extrasolar planets, and most of them are at least as massive as Jupiter. Quinn, Mayer, and their colleagues recently revisited the standard model of planet formation, investigating whether giant planets could form quickly. Astronomer Gerard Kuiper Noun 1. Gerard Kuiper - United States astronomer (born in the Netherlands) who studied the solar system and suggested in 1951 that there is a belt of comet-like debris at the edge of the solar system (1905-1973) Gerard Peter Kuiper, Kuiper made such a proposal in the early 1950s, and Alan P. Boss of the Carnegie Institution of Washington  The introduction to this article may be too long. Please help improve the introduction by moving some material from it into the body of the article according to the suggestions at (D.C.) did more extensive work beginning in the late 1980s. Boss had been using computer simulations to study the transport of angular momentum angular momentum: see momentum. angular momentum Property that describes the rotary inertia of a system in motion about an axis. It is a vector quantity, having both magnitude and direction. , or rotational motion Rotational motion The motion of a rigid body which takes place in such a way that all of its particles move in circles about an axis with a common angular velocity; also, the rotation of a particle about a fixed point in space. , and mass in the sun's protoplanetary disk. He was surprised to find that gravity could cause the swirling disk, after just a few orbits about its parent star, to suddenly fragment into clumps as big as a modest-size planet. These clumps would be so massive that they'd continue pulling in more and more material. This model is known as the gravitational-instability model. "I did not set out to upset the apple cart," Boss recalls. "Rather, I stumbled upon excellent reasons for thinking that there might be a better way to make giant planets." Also, he notes, "the extrasolar-planet discoveries have opened people's minds in general to new ideas "New Ideas" is the debut single by Scottish New Wave/Indie Rock act The Dykeenies. It was first released as a Double A-side with "Will It Happen Tonight?" on July 17, 2006. The band also recorded a video for the track. " Moreover, he says, recent calculations by other scientists have suggested that many of the solid bodies that might serve as the rocky core for Jupiter-size planets in the traditional theory would spiral into the parent star before a Jupiter could form. Further analysis by planetary scientists has shown that other effects could also cause a protoplanetary disk to become unstable and break into large fragments. For instance, within the disk, electrically charged material might pile up, triggering the disk to fragment. Or a powerful gravitational disturbance--either the tug of a star passing nearby or of a companion star to the parent--could produce instability in the disk. But the gravitational-instability model has problems of its own. Foremost, it's mathematically complicated and computationally intensive. So, no one has followed the simulations long enough and with enough precision to unequivocally demonstrate that the model allows for the formation of massive planets. "Because gravitational instability is, by definition, a highly nonlinear process, only a sophisticated computer model can properly investigate it," says Mayer. In the Nov. 29, 2002 Science, he and his colleagues describe the results of an extensive simulation based on the instability model. The team spent 2 years refining calculations to track what would happen to a protoplanetary disk over 1,000 years, more than any other simulation had considered. Mayer and his colleagues had previously devoted a decade to state-of-the-art simulations of the formation and evolution of galaxies. For that reason, "we had already developed a fast code that can run in parallel on machines with hundreds of processors," says Mayer. "It was almost natural to think of applying our tools and experience in numerical simulations to such a fundamental problem like planet formation." "I'm thrilled with what they've done," says Boss. The findings, he notes, put the instability model on a surer footing and reveal that protoplanetary disks fragment into massive clumps in just a few hundred years. DATA DEARTH Not every planetary scientist is convinced that the gravitational-instability model can supercede Verb 1. supercede - take the place or move into the position of; "Smith replaced Miller as CEO after Miller left"; "the computer has supplanted the slide rule"; "Mary replaced Susan as the team's captain and the highest-ranked player in the school" the core-accretion model. One of these skeptics is Jack Lissauer of NASA's Ames Research Center in Mountain View, Calif. He says that although the study by Quinn, Mayer, and their colleagues is the most complete test of the instability model so far, the researchers still haven't proven that a protoplanetary disk inevitably undergoes the type of instability required to form large planets rapidly. Lissauer maintains that in the team's model, the disk will first undergo a different kind of instability: Material would initially clump but then quickly spread out uniformly, hindering or preventing the large-scale clumping required to make big planets. Mayer argues that his group has shown that a protoplanetary disk can evolve through a sequence of milder instabilities, coming to a point where the disk fragments into planet forming clumps. "I have no doubt that we are seeing that our clumps will become a real giant planet," he says. Lissauer has thrown another challenge to the champions of the gravitational-instability model. He notes that his team and several others have recently demonstrated that, with refinements, the core-accretion model indeed can yield a Jupiter-mass planet within the lifetime of known protoplanetary disks. Several proposed studies may settle the controversy. In a few months, NASA NASA: see National Aeronautics and Space Administration. NASA in full National Aeronautics and Space Administration Independent U.S. is scheduled to launch the Space Infrared Telescope Facility Space Infrared Telescope Facility: see observatory, orbiting. . In conjunction with SOFIA Sofia (sōfē`ə, sō`fēə), Bulg. Sofiya, city (1993 pop. 1,114,476), capital of Bulgaria, W central Bulgaria, on a high plain surrounded by the Balkan Mts. , an infrared telescope infrared telescope A telescope, similar in operation to an optical telescope, that is designed to detect infrared radiation. Because infrared radiation is emitted by warm objects, infrared telescopes need to be shielded from local heat sources, as by mounted in an airplane, researchers plan to more accurately measure the lifetime of protoplanetary disks--especially the gaseous components so critical for making Jupiterlike planets, says Mayer. Improved infrared observations will help scientists because the dust in protoplanetary disks glows brightest at infrared wavelengths. Mayer says another test of the competing models will depend on whether astronomers can find a giant, Jupiterlike planet at a distance from its parent star comparable to that of Neptune's distance from the sun. At such a distance, the standard model would require 100 million years to make a giant planet. That's far longer than any protoplanetary disk could survive. For Boss, an important test would be a study of Jupiter's deep interior to learn how much of the planet's core is rocky. In the gravitational-instability model, the disk doesn't form clumps heavier than six times Earth's mass. So, if a mission to Jupiter were to find a core no heavier than that, that result would support the instability model. "Ten years ago, we all `knew' that the giant planets formed by core accretion," says Boss. Ten years from now, he says, textbooks may tell a different story--that giant planets grew up in a hurry. RELATED ARTICLE: Modeling planet formation Origins of underlying theory go back a couple centuries. The notion that our solar system's planets emerged from a swirling disk of gas and dust dates back more than 2 centuries. Prussian philosopher Immanuel Kant had the idea first. In a 1755 treatise, he noted that several properties indicated that all the planets arose from some common material source that had originally enveloped en·vel·op tr.v. en·vel·oped, en·vel·op·ing, en·vel·ops 1. To enclose or encase completely with or as if with a covering: "Accompanying the darkness, a stillness envelops the city" the sun. All the known planets seemed to orbit in nearly the same plane and direction about the sun, rotated in that same direction, and have moons that orbit about their planets in the same direction. French mathematician and astronomer Pierre-Simon Laplace
Pierre-Simon, marquis de Laplace (March 23 1749 - March 5 1827) was a French mathematician and astronomer whose work was pivotal to the development of mathematical presented a more quantitative argument in 1796. The origin of the solar system, he asserted, was "a large nebula nebula (nĕb`y  lə) [Lat.,=mist], in astronomy, observed manifestation of a collection of highly rarefied gas and dust in interstellar space. [that] rotated and because of the gravitation of mass to its center, a sun formed itself in the middle and condensed con·dense v. con·densed, con·dens·ing, con·dens·es v.tr. 1. To reduce the volume or compass of. 2. To make more concise; abridge or shorten. 3. Physics a. . The outer parts of the nebula broke into rings, and the rings rolled themselves into globes--the planets." In listing their reasons for assuming that planets were born from a swirling disk of matter, Laplace and Kant weren't entirely on target. In fact, Venus and Uranus, which was discovered in 1781, rotate opposite to the direction of the other planets. Moreover, some moons are now known to orbit in the opposite direction from the others. With the recent discovery of more than 100 massive extrasolar planets, there's a new focus on planet origins. The scenario proposed by Kant and Laplace provides the basis for the two major models.--R.C. |
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