Hydrogen and oxygen. On the sun two hydrogen atoms and one oxygen atom are fused at the core which keeps the suns light going and giving it more energy. The result of this is water. H2( hydrogen 2 ) O( oxygen ) h2o
With nuclear fission, a large atomic nucleus (such as a uranium nucleus) breaks apart into smaller nuclei, and energy is released. With nuclear fusion, small atomic nuclei (such as hydrogen) join to become larger nuclei, and energy is released. Fusion of hydrogen releases much more energy than any other type of either fusion or fission. Note that the dividing line between heavy nuclei and light nuclei is the iron nucleus, which is at the perfect point of nuclear stability, so that neither fusion nor fission of iron nuclei would release any energy.
Nuclear fusion is the fusion of two nuclei (atoms) which, when combined, form a highly unstable element or isotope, which almost immediately breaks up, producing energy and more, smaller nuclei to continue this chain reaction. The energy given of can be harnassed as heat to heat water into steam to turn a turbine to produce electricity, in which case the reaction would be controled, or it can be allowed to go out of control, in which case it would produce a massive explosion.
heavier elements-and i would also like to shout out to everybody in swainsboro middle school.if it wasn't for them i wouldn't be where i am today.
This would be a fusion of three helium nuclei. This would happen towards the end of a star's life, it's not occurring in the sun at present, but obviously has happened in various stars in the past, which is why we have the heavy elements in our solar system
Heavy nuclides, greater than iron or nickel, have a negative mass-energy deficit, meaning that it takes more energy to fuse them than would be released by such fusion. That is why only light nuclides, such as hydrogen are realistic candidates for fusion.
That would be nuclear fusion, like what happens in stars, when two hydrogen nuclei combine to form a helium nucleus.
With nuclear fission, a large atomic nucleus (such as a uranium nucleus) breaks apart into smaller nuclei, and energy is released. With nuclear fusion, small atomic nuclei (such as hydrogen) join to become larger nuclei, and energy is released. Fusion of hydrogen releases much more energy than any other type of either fusion or fission. Note that the dividing line between heavy nuclei and light nuclei is the iron nucleus, which is at the perfect point of nuclear stability, so that neither fusion nor fission of iron nuclei would release any energy.
With nuclear fission, a large atomic nucleus (such as a uranium nucleus) breaks apart into smaller nuclei, and energy is released. With nuclear fusion, small atomic nuclei (such as hydrogen) join to become larger nuclei, and energy is released. Fusion of hydrogen releases much more energy than any other type of either fusion or fission. Note that the dividing line between heavy nuclei and light nuclei is the iron nucleus, which is at the perfect point of nuclear stability, so that neither fusion nor fission of iron nuclei would release any energy.
Shortening
Because if the nuclei touches any thing it would fuse with it or destroy it. Making it undetectable and not available for reaction.
It would very likely explode, but if you are lucky it will fizz and burn a hole in the beaker. But, do NOT ever combine colored fusion and still fusion into a beaker. The results will always be dangerous.
Nuclear fusion is the fusion of two nuclei (atoms) which, when combined, form a highly unstable element or isotope, which almost immediately breaks up, producing energy and more, smaller nuclei to continue this chain reaction. The energy given of can be harnassed as heat to heat water into steam to turn a turbine to produce electricity, in which case the reaction would be controled, or it can be allowed to go out of control, in which case it would produce a massive explosion.
heavier elements-and i would also like to shout out to everybody in swainsboro middle school.if it wasn't for them i wouldn't be where i am today.
This would be a fusion of three helium nuclei. This would happen towards the end of a star's life, it's not occurring in the sun at present, but obviously has happened in various stars in the past, which is why we have the heavy elements in our solar system
Scientists are researching how to achieve nuclear fusion, a process that releases a large amount of energy by combining atomic nuclei. The sun is powered by fusion reactions, where hydrogen atoms combine to form helium. The goal of fusion research is to harness this process and create clean, limitless energy for the future.
Heavy nuclides, greater than iron or nickel, have a negative mass-energy deficit, meaning that it takes more energy to fuse them than would be released by such fusion. That is why only light nuclides, such as hydrogen are realistic candidates for fusion.
one cell with two identical nuclei