What a blast!Take a dense, collapsed star, set a helium-rich star in orbit around it, and you've got the ingredients for a series of explosions, each lasting about 10 seconds and releasing as much energy as the sun does in an entire year. Such eruptions can happen several times a day on the surface of a neutron star--the superdense su·per·dense adj. Of or relating to an extreme condition in which matter is forced into nonclassical states, as when electrons are forced into protons, leaving only neutrons, or the matter is compressed beyond this point into a singularity. cinder cin·der n. 1. a. A burned or partly burned substance, such as coal, that is not reduced to ashes but is incapable of further combustion. b. A partly charred substance that can burn further but without flame. left behind when a massive star jettisons its outer layers and collapses. Now, astronomers Famous astronomers and astrophysicists include: Directory: A B C D E F G H I J K L M N O P Q R S T U V W X Y Z A
In the more common explosions, a neutron star neutron star, extremely small, extremely dense star, about double the sun's mass but only a few kilometers in radius, in the final stage of stellar evolution. Astronomers Baade and Zwicky predicted the existence of neutron stars in 1933. , as heavy as the sun but only 20 kilometers wide, snatches gas from a nearby companion rich in helium. As the stolen helium piles up on the neutron star's surface, helium nuclei fuse explosively, briefly hurling hurling, outdoor ball and stick game similar to field hockey (see hockey, field). The national pastime of Ireland, it was played for many centuries before the Gaelic Athletic Association standardized the rules in 1884. a torrent of X rays into space. Last year, astronomers using the Rossi X ray Timing Explorer satellite examined a neutron star and its partner that lie some 20,000 light-years from Earth. Scientists had previously observed short-lived outbursts from this two-star system, known as 4U 1820-30. But during the new study, the system emitted a flare that lasted for 3 hours and spewed as much energy as the sun does in a century. Tod E. Strohmayer of NASA's Goddard Space Flight Center The Goddard Space Flight Center (GSFC) is a major NASA space research laboratory established on May 1, 1959 as NASA's first space flight center. GSFC employs approximately 10,000 civil servants and contractors, and is located approximately 6.5 miles northeast of Washington, D.C. in Greenbelt, Md., and his colleagues suggest that the flare stemmed from the neutron star's short-lived helium explosions. When three helium nuclei fuse and ignite, they produce a carbon nucleus. Over time, this carbon ash may build up under layers of new helium captured from the neutron star's companion. When enough carbon nuclei accumulate, they would squeeze together to make even heavier elements, liberating a tremendous amount of energy in the process--about 1,000 times as much as a helium explosion produces. These rare explosions would last for hours because the energy generated by the carbon, buried some 100 meters beneath the neutron star's surface, would take time to leak out to be divulged gradually or clandestinely; to become public; as, the facts leaked out s>. See also: Leak , Strohmayer notes. He estimates that the explosion observed by Rossi required about a billion trillion kilograms of carbon heated to a billion kelvins. Theorists calculate that the neutron star seizes matter at a million billion kilograms per second. At that rate, it would take 1 to 2 years to accumulate enough carbon to generate the explosion, Strohmayer reported last month at a meeting of the American Astronomical Society The American Astronomical Society (AAS, sometimes pronounced "double-A-S") is a US society of professional astronomers and other interested individuals, headquartered in Washington, DC. in Honolulu. Carbon explosions are "the best bet" to explain the observations, says Edward F. Brown of the University of Chicago. However, his calculations suggest that a neutron star's surface can't reach temperatures as high as 1 billion kelvins. To ignite carbon at a slightly more modest temperature, the star would require a billion times as much of the material, and it would take a century to stockpile stock·pile n. A supply stored for future use, usually carefully accrued and maintained. tr.v. stock·piled, stock·pil·ing, stock·piles To accumulate and maintain a supply of for future use. that much carbon, Brown notes. Deeming it unlikely that the Rossi craft happened to record a once-in-a-century explosion, Brown says he's trying to determine if the neutron star could reach temperatures higher than he had at first calculated or if the star could have pulled material from its partner even more rapidly than Strohmayer assumed. |
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