Results from a solar cycle of neutrino data.Since it began watching the sun in 1987, Japan's Kamiokande neutrino detector A neutrino detector is a device designed to detect neutrinos. Because neutrinos are very weakly interacting, neutrino detectors must be very large in order to detect a significant number of neutrinos. has provided data important for understanding how nuclear fusion reactions power the sun and for testing theories of stellar evolution stellar evolution, life history of a star, beginning with its condensation out of the interstellar gas (see interstellar matter) and ending, sometimes catastrophically, when the star has exhausted its nuclear fuel or can no longer adjust itself to a stable . Fusion reactions in the sun's core produce huge quantities of neutrinos, elusive subatomic particles that interact weakly with ordinary matter. Earth-based detectors pick up only a tiny fraction of these particles. By the time it was shut down last year to make way for a considerably more sensitive experiment, the original Kamiokande detector had accumulated data covering nearly a complete solar cycle solar cycle Period in which several important kinds of solar activity repeat, discovered in 1843 by Samuel Heinrich Schwabe (1789–1875). Lasting about 22 years on average, it includes two 11-year cycles of sunspots, whose magnetic polarities alternate between the , the roughly 11-year period during which sunspot sunspot Cooler-than-average region of gas on the Sun's surface associated with strong local magnetic activity. Sunspots appear as dark spots, but only in contrast with the surrounding photosphere, which is several thousand degrees hotter. activity goes from a minimum to a maximum and back to a minimum. Earlier studies, based on data from a different solar neutrino detector, had hinted at a correlation between the number of neutrinos arriving at a collector and solar activity, with the detection rate decreasing as the number of sunspots sunspots, dark, usually irregularly shaped spots on the sun's surface that are actually solar magnetic storms. The Chinese recorded dark features on the sun seen with the naked eye in 28 B.C. increases (SN: 12/8/90, p. 358). If such a connection had been confirmed, it would have provided evidence that the neutrino neutrino (n  trē`nō) [Ital.,=little neutral (particle)], elementary particle with no electric charge and a very small mass emitted during the decay of certain other particles. has a mass and could change from one type of neutrino to another (SN: 5/18/96, p. 319). In their final report, however, members of the Kamiokande collaboration conclude that they observed no month-to-month or year-to-year variations in the number of neutrinos detected that would match the pattern of solar activity throughout this period. "No strong correlation of the solar neutrino flux with the sunspot numbers was found within experimental [uncertainties]," Yoshiyuki Fukuda of the Institute for Cosmic Ray Research at the University of Tokyo “Todai” redirects here. For the restaurant called Todai, see Todai (restaurant). The University of Tokyo (東京大学 and the other members of the Kamiokande collaboration report in the Aug. 26 Physical Review Letters Physical Review Letters is one of the most prestigious journals in physics.[1] Since 1958, it has been published by the American Physical Society as an outgrowth of The Physical Review. . Located in a mine about 200 kilometers west of Tokyo and a kilometer underground, to shield it from less penetrating rays, the Kamiokande detector consisted of a cylindrical tank containing 3,000 tons of pure water. Sensitive photodetectors lining the tank's walls picked up light flashes generated by speeding electrons knocked aside on the rare occasions-averaging less than once a day-when neutrinos interacted with water. The detector was the first to show directly that the observed neutrinos came from the direction of the sun rather than from other possible sources (SN: 10/28/89, p. 280). The energy of the neutrinos indicated that they originated in the decay of boron-8, an isotope created near the end of the chain of nuclear fusion reactions fueling the sun. Kamiokande's detection rate of boron-8 neutrinos was about half that predicted by theorists calculating the sun's output using the standard solar model The Standard Solar Model (SSM) is the best current physical model of our sun. Very generally, in the Standard Solar Model the sun is a ball of mostly hydrogen plasma which is held together through self gravitation. . Other experiments have found a similar, persistent shortfall, suggesting either that models of the sun's interior are incomplete or that neutrino physics may be more complicated than expected. The Super Kamiokande detector, which replaces the original Kamiokande, started up April 1. It is expected to detect about 100 times as many neutrinos per day as its predecessor. |
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