Nuclear fusion: Difference between revisions
Pat Palmer (talk | contribs) (starter sentence) |
mNo edit summary |
||
| (4 intermediate revisions by 2 users not shown) | |||
| Line 1: | Line 1: | ||
{{subpages}} | {{subpages}} | ||
'''Nuclear | '''Nuclear fusion''' is a process in which small atomic nuclei fuse and release energy. In a hydrogen bomb, fusion of deuterium and tritium (two isotopes of hydrogen) releases four times as much energy as the same mass of uranium in a fission bomb.<ref name=fusionEnergy/> | ||
To derive useful power from nuclear fusion, the nuclei need to be confined at pressures and temperatures far higher than any material can withstand. There are two ways to do this - either with magnetic fields, which force the charged particles to circle around rather that escape, or with "inertial confinement" like in a bomb, but driven by lasers on a much smaller scale.<ref name=magnetoInertial/> | |||
Both fission and fusion produce small amounts of nuclear waste. The advantages of fusion are that it does not have the anti-nuclear stigma of fission, and the reactors will be so expensive as to not threaten an end to the fossil fuel industry. | |||
{{reflist|refs= | |||
<ref name=fusionEnergy>On a mass basis, the D-T fusion reaction releases over four times as much energy as uranium fission.[https://world-nuclear.org/information-library/current-and-future-generation/nuclear-fusion-power.aspx Nuclear Fusion Power] World Nuclear Association, 2022. | |||
</ref> | |||
<ref name=magnetoInertial>Recently there has been some excitement about a hybrid technique, using inertia from massive pistons compressing a magnetic field, which keeps the hot plasma away from the reactor walls.[https://www.helionenergy.com/ Helion Energy] | |||
</ref> | |||
}}[[Category:Suggestion Bot Tag]] | |||
Latest revision as of 11:00, 27 September 2024
Nuclear fusion is a process in which small atomic nuclei fuse and release energy. In a hydrogen bomb, fusion of deuterium and tritium (two isotopes of hydrogen) releases four times as much energy as the same mass of uranium in a fission bomb.[1]
To derive useful power from nuclear fusion, the nuclei need to be confined at pressures and temperatures far higher than any material can withstand. There are two ways to do this - either with magnetic fields, which force the charged particles to circle around rather that escape, or with "inertial confinement" like in a bomb, but driven by lasers on a much smaller scale.[2]
Both fission and fusion produce small amounts of nuclear waste. The advantages of fusion are that it does not have the anti-nuclear stigma of fission, and the reactors will be so expensive as to not threaten an end to the fossil fuel industry.
- ↑ On a mass basis, the D-T fusion reaction releases over four times as much energy as uranium fission.Nuclear Fusion Power World Nuclear Association, 2022.
- ↑ Recently there has been some excitement about a hybrid technique, using inertia from massive pistons compressing a magnetic field, which keeps the hot plasma away from the reactor walls.Helion Energy