Energy is released during nuclear fission or fusion. The mass deficit (apparent loss of mass resulting from the reaction) is represented by a related (e = mc2) release of energy. Note, however, that neither mass nor energy is created or destroyed - it is simply moved from one frame of reference to another.
Nuclear fusion doesn't produce energy.
The process generating solar energy is one of nuclear fusion.
Nuclear processes that can release large amounts of energy.
Nuclear energy typically refers to fission, where atoms are split to release energy. Fusion energy involves merging atoms to release energy, mimicking the process that powers the sun. Fusion has the potential to generate more energy and produce less waste compared to fission.
The difference between Fusion and Fission is that Fission is easier to do and produces more energy than fusion reactions. However fission can be dangerous and is used in Nuclear reactors. Fusion however is safer and produces less energy but safely. It is quite difficult to cause a Fusion reaction however.
Definition: energy from nuclear fission or fusion: the energy released by nuclear fission or fusion
The two types of nuclear energy are nuclear fission nuclear fusion. In nuclear fission, the nuclei of the atoms are split. In nuclear fusion, as the name suggests, the nuclei of the atoms are joined together.
fission and/or fusion
Energy from nuclear fusion is around 400 times more than that of nuclear fission for same mass.
Nuclear fusion doesn't produce energy.
The process generating solar energy is one of nuclear fusion.
Nuclear processes that can release large amounts of energy.
Nuclear fission involves splitting atoms to release energy, while nuclear fusion involves combining atoms to release energy.
Nuclear energy.
Nuclear energy.
Nuclear energy is produced by both fission and fusion processes.
The sun's energy is generated through nuclear fusion.