WebJul 8, 2024 · Neutron stars and black holes are born from dying stars. As a star runs out of hydrogen to fuse into helium, it becomes unstable and collapses. If the star is large enough, it will go supernova, and the core will become a neutron star. If the star is even larger, the core will become a black hole. WebJan 17, 2024 · The star could be high or low in mass, which determines the longevity and fate of every star. High-mass stars exist for a lesser amount of time and their eventual fate could be an explosive end in a supernova and a subsequent black hole.
Background: Dispersion of Elements - NASA
WebNov 10, 2024 · Within more massive stars, whose stronger gravity creates more pressure and heat, elements beyond oxygen can fuse. But this process can continue only until iron (element No. 26) forms at... WebDec 23, 2024 · For example, gold, platinum, and uranium are only produced via the r-process. By the early 1970s, scientists knew that the s-process happens in the … hill view packing gustine ca
Can Giant Stars Fuse To Form Gold? - Science ABC
WebDec 16, 2013 · The Milky Way mostly has multiple star systems. Several stars can be orbiting a common center of gravity. Many are great distances, but some can have orbits … WebClosed 5 years ago. I know larger stars can fuse heavier and heavier elements up to iron where it stops because fusing iron requires more energy than it releases, causing a collapse and supernova. Why does fusing iron in a stellar core use more energy than it releases? supernova Share Improve this question Follow edited Jun 14, 2024 at 16:52 WebHaving achieved iron, the star has wrung all the energy it can out of nuclear fusion - fusion reactions that form elements heavier than iron actually consume energy rather than produce it. The star no longer has any way to support its own mass, and the iron core collapses. In just a matter of seconds the core shrinks from roughly 5000 miles ... smart business dealmakers charlotte