2012
DOI: 10.2478/s11534-012-0031-1
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Tachyonic field theory and neutrino mass running

Ulrich Jentschura

Abstract: Abstract:In this paper three things are done. (i) We investigate the analogues of Cerenkov radiation for the decay of a superluminal neutrino and calculate the Cerenkov angles for the emission of a photon through a W loop, and for a collinear electron-positron pair, assuming the tachyonic dispersion relation for the superluminal neutrino. The decay rate of a freely propagating neutrino is found to depend on the shape of the assumed dispersion relation, and is found to decrease with decreasing tachyonic mass of… Show more

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Cited by 9 publications
(10 citation statements)
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References 60 publications
(180 reference statements)
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“…Adding to the difficulties, we notice that recent experimental claims regarding the conceivable observation of highly superluminal neutrinos have turned out to be false. One may point out that a relative deviation v = c (1+δ) with δ ∼ 10 −5 at E ∼ 30 GeV, as claimed by some recent experimental collaborations, would correspond to a negative neutrino mass square in the order of ∼ −(100 MeV) 2 , if one assumes a Lorentz-invariant dispersion relation [34]. Still, there is at present no conclusive answer regarding the conceivable superluminality of at least one neutrino flavor [35][36][37][38][39], and it is intriguing that all available direct measurements of the neutrino mass square have resulted in negative expectation values, still compatible with zero within experimental uncertainty, whereas published experimental best estimates for the neutrino speed [40][41][42][43] have been superluminal, again still compatible with the speed of light within experimental error.…”
Section: B Tachyonic Dirac Equation and Neutrinos: Possible Connectionsmentioning
confidence: 89%
“…Adding to the difficulties, we notice that recent experimental claims regarding the conceivable observation of highly superluminal neutrinos have turned out to be false. One may point out that a relative deviation v = c (1+δ) with δ ∼ 10 −5 at E ∼ 30 GeV, as claimed by some recent experimental collaborations, would correspond to a negative neutrino mass square in the order of ∼ −(100 MeV) 2 , if one assumes a Lorentz-invariant dispersion relation [34]. Still, there is at present no conclusive answer regarding the conceivable superluminality of at least one neutrino flavor [35][36][37][38][39], and it is intriguing that all available direct measurements of the neutrino mass square have resulted in negative expectation values, still compatible with zero within experimental uncertainty, whereas published experimental best estimates for the neutrino speed [40][41][42][43] have been superluminal, again still compatible with the speed of light within experimental error.…”
Section: B Tachyonic Dirac Equation and Neutrinos: Possible Connectionsmentioning
confidence: 89%
“…This suggests that such particles are theoretically possible but are unstable and do not decrease their energy by increasing their velocity, as the classical tachyon theory would predict [26]. This hypothesis has been deeply investigated by Jentschura [33], who proposed possible mechanisms of decay. The first validation test of the obtained solutions is represented by the study of the Zitterbewegung effect.…”
Section: Discussionmentioning
confidence: 99%
“…Moreover, as usually expected in pair creation, the module of the vector impulse is the same for both particles n andn. From the second equation of (20), we obtain the following:…”
Section: Space-like Pair Productionmentioning
confidence: 99%
“…Since b > 1 and q  cos 1, we can always find a superluminal velocity u t and an angle θ for which the product b q cos is unitary so that equation (21) is equal to the first equation of (20). Therefore, from a photon, it is always possible to create a/ n n tachyon pair, even in vacuum, due to the fact that, in the momentum-energy dispersion relation of a tachyon, the mass term is always negative.…”
Section: Space-like Pair Productionmentioning
confidence: 99%
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