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The first kind of muon–catalyzed fusion to be observed experimentally, by L.W. Alvarez et al., [6] was protium (H or 1 H 1) and deuterium (D or 1 H 2) muon-catalyzed fusion. The fusion rate for p–d (or pd) muon-catalyzed fusion has been estimated to be about a million times slower than the fusion rate for d–t muon-catalyzed fusion. [7 ...
In muon-catalyzed fusion there are more fusions because the presence of the muon causes deuterium nuclei to be 207 times closer than in ordinary deuterium gas. [138] But deuterium nuclei inside a palladium lattice are further apart than in deuterium gas, and there should be fewer fusion reactions, not more. [133]
Muon-catalyzed fusion is a technical application of muonic atoms. Other muonic atoms can be formed when negative muons interact with ordinary matter. [4] The muon in muonic atoms can either decay or get captured by a proton. Muon capture is very important in heavier muonic atoms, but shortens the muon's lifetime from 2.2 μs to only 0.08 μs. [4]
As of 2007 producing muons required more energy than can be obtained from muon-catalyzed fusion. [ 50 ] Lattice confinement fusion : Lattice confinement fusion ( LCF ) is a type of nuclear fusion in which deuteron -saturated metals are exposed to gamma radiation or ion beams, such as in an IEC fusor , avoiding the confined high-temperature ...
Penning fusion (PFX, LANL) Plasma jets (HyperV, Chantilly) Magnetized target fusion with mechanical compression (General Fusion, Burnaby) Field-reversed colliding beams (Tri-Alpha) Muon-catalyzed fusion (Berkeley, Alvarez) Dense Plasma Focus (Focus fusion, Lawrenceville Plasma Physics, Lerner) Rotating lithium wall (RWE, Maryland)
Articles dealing specifically with using this process to produce useful power are contained in the subcategory Fusion power. Articles about nuclear processes that are speculative or poorly understood (like cold fusion ), or whose potential for power production is remote (like muon-catalyzed fusion ) are kept in the main category.
Muon decay almost always produces at least three particles, which must include an electron of the same charge as the muon and two types of neutrinos. Like all elementary particles, the muon has a corresponding antiparticle of opposite charge (+1 e) but equal mass and spin: the antimuon (also called a positive muon). Muons are denoted by μ −
Since the muon has a mass about 200 times greater than that of an electron, their orbitals are commensurately smaller (hence the possibility of muon-catalyzed fusion). I don't know for sure which electrons they'd displace, but I'd expect them to fall into 1s orbitals first, followed by 2s, 2p, . . . -- same as electrons, just closer in.