http://www.universetoday.com/am/publish/bceti_brighter.html Giant Star Generates a Massive Amount of X-Rays Summary - (Jan 4, 2005) The Chandra X-Ray observatory took this image of an unusual star called Beta Ceti. It's only three times more massive than our own Sun, but it radiates 2,000 times more X-ray power. Astronomers believe it's putting out so much X-ray radiation because it's at an advanced stage of stellar evolution called "core helium burning". For its first billion years, Beta Ceti was converting hydrogen to helium through fusion, but it ran out of hydrogen fuel and became a red giant star. Then it started to shrink again, and temperatures rose to 100 million degrees; hot enough that it could begin fusing helium atoms together to create carbon atoms. http://chandra.harvard.edu/photo/2004/bceti/ Beta Ceti: Giant Star's Corona Brightens with Age Beta Ceti is a bright, giant star with a hot corona that radiates about 2,000 times more X-ray power than the Sun. Scientists suspect that this X-ray activity is somehow related to its advanced stage of evolution called core helium burning. During this stage, the core of the star is very hot (more than a hundred million degrees Celsius) and converting helium to carbon via nuclear fusion reactions. Using the theory of how stars evolve, we can reconstruct the history of Beta Ceti, a star with a mass of about 3 Suns. Over the first billion years of its existence, Beta Ceti was powered by nuclear fusion reactions converting hydrogen to helium in the core. After the hydrogen in the core was exhausted, the central region of the star contracted until hydrogen gas around the helium core became hot and dense enough for hydrogen fusion reactions to ignite there. This powerful new energy source caused the outer regions of the star to expand greatly and cool. At this point Beta Ceti became a red giant. During the red giant phase, Beta Ceti would have been a very weak X-ray source. After about 10 million years, the core of the star contracted and heated to more than 100 million degrees, enabling helium fusion reactions to occur there. In this core helium burning stage, which will last 100 million years or more, the overall diameter of the star has shrunk to about 20 times that of the Sun and the surface temperature has increased, so it is no longer a red giant star. <><><><><><><><> 100 million degrees is about the temperature in Tokamak fusion reactors like ITER -- so why the need for breeding tritium for the D-T fusion reaction ? .....why not just burn abundant He-4 ? .....could it have something to do with reaction rates ? ....maybe fusion reactors aren't quite like the Sun & stars after all, as the media like to claim ? -- No virus found in this outgoing message. Checked by AVG Anti-Virus. Version: 7.0.300 / Virus Database: 265.6.8 - Release Date: 1/3/2005
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