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| '''Muon-catalyzed fusion''' is a process that allows fusion at room temperature. Although it does allow for fusion, it does not currently provide anywhere close to ] energy. It is sometimes known as ] although this term is no longer often used as it can create confusion with other scientifically unestablished forms of room temperature fusion. | '''Muon-catalyzed fusion''' is a process that allows fusion at room temperature. Although it does allow for fusion, it does not currently provide anywhere close to ] energy. It is sometimes known as ] although this term is no longer often used as it can create confusion with other scientifically unestablished forms of room temperature fusion. | ||
| In muon-catalyzed fusion, ] and ] nuclei form atoms with ]s, which are essentially heavy electrons. The muons orbit very close to the nuclei, shielding the positive charge of the nuclei so the nuclei can move close enough to fuse. | In muon-catalyzed fusion, ] and ] nuclei form atoms with ]s, which are essentially heavy electrons. The muons orbit very close to the nuclei, shielding the positive charge of the nuclei so the nuclei can move close enough to fuse. | ||
| The main problem with muon-catalyzed fusion is that muons are unstable, and hence there needs to be means of producing muons and muons must be arranged to catalyze as many reactions as possible before decaying. | The main problem with muon-catalyzed fusion is that muons are unstable, and hence there needs to be means of producing muons and muons must be arranged to catalyze as many reactions as possible before decaying. | ||
Revision as of 01:04, 4 October 2003
Muon-catalyzed fusion is a process that allows fusion at room temperature. Although it does allow for fusion, it does not currently provide anywhere close to breakeven energy. It is sometimes known as cold fusion although this term is no longer often used as it can create confusion with other scientifically unestablished forms of room temperature fusion.
In muon-catalyzed fusion, deuterium and tritium nuclei form atoms with muons, which are essentially heavy electrons. The muons orbit very close to the nuclei, shielding the positive charge of the nuclei so the nuclei can move close enough to fuse.
The main problem with muon-catalyzed fusion is that muons are unstable, and hence there needs to be means of producing muons and muons must be arranged to catalyze as many reactions as possible before decaying.