A Comet's Long Tail Tickles Ulysses.When a newly discovered comet named Hyakutake passed near Earth about 4 years ago, it made a major spectacle of itself. As well as flaunting two dust tails, it sported a ghostly bluish-white stream of charged particles, extending a third of the way across the sky (SN: 6/1/96, p. 346). This ion tail, it now turns out, went on for an even longer stretch. A recent review of 1996 data from the Ulysses spacecraft reveals this tail as the longest ever recorded. Spanning at least 571 million kilometers--about 3.5 times the Earth-sun distance--the tail might have extended to the fringes of the 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. , researchers report in the April 6 NATURE. Astronomers say that they are amazed to find an intact ion tail so far from its parent. This is the first time that the tail of a known comet has been detected by analyzing the solar wind solar wind, stream of ionized hydrogen—protons and electrons—with an 8% component of helium ions and trace amounts of heavier ions that radiates outward from the sun at high speeds. , the breeze of charged particles that blows out of the sun. Scientists had thought that the only way to sample comet material was to fly costly missions close by the object. They now plan to look for undetected comets simply by searching for their tails. "A spacecraft could travel through regions of the solar system picking up ions from the many invisible comet tails that probably crisscross our solar system," says George Gloeckler of the University of Maryland, College Park The University of Maryland, College Park (also known as UM, UMD, or UMCP) is a public university located in the city of College Park, in Prince George's County, Maryland, just outside Washington, D.C., in the United States. . He coauthored one of the two Ulysses studies in the NATURE issue. A NASA-European Space Agency mission launched in 1990, Ulysses explores the polar regions polar regions: see Antarctica; Arctic, the. of the sun. Gloeckler and his colleagues weren't hunting comets when they sifted through data on the composition of the solar wind. They were looking for Looking for In the context of general equities, this describing a buy interest in which a dealer is asked to offer stock, often involving a capital commitment. Antithesis of in touch with. changes in the wind that would indicate a solar eruption. However, when they examined the composition of the solar wind hitting Ulysses on May 1, 1996, the researchers found something puzzling. The population of highly ionized i·on·ize tr. & intr.v. i·on·ized, i·on·iz·ing, i·on·iz·es To convert or be converted totally or partially into ions. i gas particles--the main constituents of the solar wind---abruptly dropped to a fifth of its previous value. At the same time, the density of singly ionized particles, including carbon and oxygen, rose dramatically. Such ions are rare in the solar wind but common in the tails of the few comets, such as Halley's, that astronomers have examined extensively. Whenever the solar wind runs into an ion tail, it carries the tail material along with it. But if the craft had intercepted a comet's tail, where was the comet? No known comets resided at Ulysses' distance from the sun, nearly four times the Earth-sun separation. Using the velocity of the solar wind, the team calculated that 8 days earlier, Comet Hyakutake had been more than half a billion kilometers distant, yet in the right place--along the line connecting the sun and the spacecraft--to have generated the ions. A team based in London came to the same conclusion after analyzing data from a magnetometer aboard Ulysses. That detector revealed that on May 1, 1996, the magnetic field traveling along with the solar wind had an unusual configuration, report Geraint H. Jones and Andre Balogh of Imperial College and Timothy S. Horbury of Queen Mary and Westfield College Queen Mary and Westfield College - (QMW) One of the largest of the multi-faculty schools of the University of London. QMW has some 6000 students and over 600 teaching and research staff organised into seven faculties. . The field exhibited a hairpin hairpin a secondary structure that occurs in single-strand RNA during protein synthesis in which the strand turns back on itself. The structure is the result of base pairing and hydrogen bond formation. shape, a sign that the solar wind had run into some dense obstacle and the magnetic field had draped drape v. draped, drap·ing, drapes v.tr. 1. To cover, dress, or hang with or as if with cloth in loose folds: draped the coffin with a flag; a robe that draped her figure. around it. Comets are prime suspects in such behavior: The high density of ions near the core of a comet is highly effective at slowing the solar wind. The magnetic field disturbance indicated that the tail was curving away from the sun, the researchers say. This geometry is characteristic of a rapidly moving comet, such as Hyakutake, at its closest approach to the sun. "The two papers together make a very convincing case," says comet researcher John C. Brandt of the University of New Mexico The University of New Mexico (UNM) is a public university in Albuquerque, New Mexico. It was founded in 1889. It also offers multiple bachelor's, master's, doctoral, and professional degree programs in all areas of the arts, sciences, and engineering. in Albuquerque. He suggests that the ion tail remained intact as it was pushed more than half a billion kilometers because the polar solar wind is remarkably steady. Had the tail been carried by the sun's gusty gust·y adj. gust·i·er, gust·i·est 1. Blowing in or marked by gusts: a gusty storm. 2. Characterized by sudden outbursts. equatorial wind, it might have been torn apart, Brandt speculates. If planetary scientists can find small comets by detecting the tails, he notes, they will be better able to test models that describe how these amalgams of dust and ice formed in the early solar system. |
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