Measurement of the neutrino velocity with the OPERA detector in the CNGS beam using the 2012 dedicated data

Adam, Thomas; Agafonova, N.; Aleksandrov, A.; Anokhina, A.; Aoki, Shigeki; Ariga, A.; Ariga, T.; Autiero, D.; Badertscher, A.; Dhahbi, Anis Ben; Beretta, M.; Bertolin, A.; Bozza, C.; Brugière, T.; Brugnera, R.; Brunet, F.; Brunetti, G.; Buettner, B.; Buontempo, S.; Carlus, B.; Cavanna, F.; Cazes, A.; Chaussard, L.; Chernyavsky, M.; Chiarella, V.; Chukanov, A.; D’Ambrosio, N.; Lellis, G. De; Serio, M. De; Sanchez, P. del Amo; Crescenzo, A. Di; Ferdinando, D. Di; Marco, N. Di; Dmitrievsky, Sergey; Dracos, M.; Duchesneau, D.; Dusini, S.; Dzhatdoev, T.; Ebert, J.; Ereditato, A.; Esposito, L. S.; Favier, Jean; Felici, G.; Ferber, T.; Fini, R. A.; Fukuda, Tsutomu; Garfagnini, A.; Giacomelli, G.; Girerd, C.; Goellnitz, C.; Goldberg, J.; Golubkov, D.; Gornushkin, Y.; Grella, G.; Grianti, F.; Guérin, C.; Guler, A. M.; Gustavino, C.; Hagner, C.; Hamada, K.; Hara, T.; Hierholzer, M.; Hollnagel, A.; Ishida, Hirokazu; Ishiguro, K.; Jakovčić, K.; Jollet, C.; Kamiscioglu, C.; Kamiscioglu, M.; Kawada, J.; Kim, J. H.; Kim, S. H.; Kimura, Mitsuhiro; Kitagawa, N.; Kliček, B.; Kodama, K.; Komatsu, M.; Köse, U.; Kreslo, I.; Lauria, A.; Lazzaro, C.; Lenkeit, J.; Ljubičić, A.; Longhin, A.; Malgin, A. S.; Mancini‐Terracciano, C.; Mandrioli, G.; Marteau, J.; Matsuo, T.; Matveev, V.; Mauri, N.; Medinaceli, E.; Meregaglia, A.; Migliozzi, P.; Mikado, S.; Monacelli, P.; Montesi, M.C.; Morishima, Keisuke; Moser, U.; Muciaccia, M. T.; Nakamura, Mitsuhiro; Nakano, T.; Nakatsuka, Y.; Naumov, D.; Nikitina, V.; Ogawa, S.; Olchevsky, A.; Ozaki, K.; Palamara, O.; Paoloni, A.; Park, B. D.; Park, I. G.; Pastore, A.; Patrizii, L.; Pennacchio, E.; Pessard, H.; Pistillo, C.; Подгрудков, Д.; Polukhina, N.; Pozzato, M.; Pretzl, K.; Pupilli, F.; Rescigno, R.; Roda, M.; Роганова, Т. М.; Rokujo, H.; Rosa, G.; Rostovtseva, I.; Rubbia, A.; Russo, A.; Ryazhskaya, O. G.; Sato, Osamu; Sato, Yoshihiro; Schembri, Adam; Schmidt‐Parzefall, W.; Schuler, J.; Shakiryanova, I. R.; Sheshukov, A.; Shibuya, H.; Shoziyoev, G.; Simone, S.; Sioli, M.; Sirignano, C.; Sirri, G.; Song, J.; Spinetti, M.; Stančo, L.; Starkov, N.; Stellacci, Simona Maria; Stipčević, M.; Strauss, T.; Takahashi, Satoru; Tenti, M.; Terranova, F.; Tioukov, V.; Tolun, P.; Tufanli, S.; Vilain, P.; Vladimirov, M. S.; Votano, L.; Vuilleumier, J. L.; Wilquet, G.; Wonsak, B.; Wurtz, Jacques; Yoon, C. S.; Yoshida, Junshi; Zaitsev, Yu.; Zemskova, S.; Zghiche, A.; Zimmermann, R.

doi:10.1007/jhep01(2013)153

Cited by 26 publications

(33 citation statements)

References 8 publications

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“…Along the same lines, one notices that c 1 is unphysical in the OPERA [2] experiments.The same is true for other neutrino velocity experiments [1] and [3]. Furthermore, because the muon neutrino mass being negligible, one finds out that in fact c 3 ≃ c. To verify this perturbative result, one performs the calculation also with exact non-perturbative expression for c 3 .…”

Section: Introductionmentioning

confidence: 67%

“…Both mistakes were found and the OPERA collaborators made proper corrections and after a precise measurment of the neutrino velocity in agreement with c, the velocity of light, published the result in [1] (version 3). OPERA collaborators also published the results from a measurement of a special bunched neutrino beam [2] (version 2) giving the precision measurement of the muon neutrino and muon anti-neutrino velocities, in good agreement with c, the velocity of light. Other, so called Gran Sasso laboratory repeated the measurements and obtained c, the velocity of light, for the neutrino velocity [3] (version 2).…”

Section: Introductionmentioning

confidence: 97%

“…There have been the whole series of neutrino velocity experiments such as the OPERA collaborations with the detector in the CNGS beam [1] (versions 1, 2 and 3), the OPERA detector the CNGS beam using the 2012 dedicated data [2] (versions 1 and 2) as well as the ICARUS detector in the CNGS beam [3] (versions 1 and 2).…”

Section: Introductionmentioning

confidence: 99%

“…In Section 3, after deducing the three flavor neutrino masses, one finds out that the physical parameter structure of the OPERA [2] muon neutrino velocity experiment is such that the Taylor series expansion, in terms of (mv 2 /E), strongly suggests c 3 as the luminal solution. Along the same lines, one notices that c 1 is unphysical in the OPERA [2] experiments.The same is true for other neutrino velocity experiments [1] and [3].…”

Section: Introductionmentioning

confidence: 99%

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Theoretical particle limiting velocity from the bicubic equation: Neutrino example

Šoln¹

2014

phys essays

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There has been a lot of interest in measuring the velocities of massive elementary particles, particularly the neutrinos. Some neutrino experiments at first observed superluminal neutrinos, thus violating the velocity of light c as a limiting velocity. But, after eliminating some mistakes, such as, for the OPERA experiments plugging the cable correctly and calibrating the clock correctly, the measured neutrino velocity complied with c. Pursuing the theoretical side of particle limiting velocities, here directly from the special relativistic kinematics, in which all physical quantities

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Section: Introductionmentioning

confidence: 67%

Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Theoretical particle limiting velocity from the bicubic equation: Neutrino example

Šoln¹

2014

phys essays

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“…The effect spurred lively debates, got enormous media coverage, and triggered independent measurements by the neighbor ICARUS experiment; dedicated beam runs were performed to collect data less affected by jitter effects in the timing structure of the beam. After several months of investigations the effect was finally understood to be due to a single large source of systematic uncertainty, which had not been accounted for: the delay was produced by a loose signal cable [16]. In the same year the CDF collaboration showed a large, 4σ signal at 145 GeV in the mass distribution of jet pairs produced in association with leptonic W boson decays in the Tevatron 1.96 TeV proton-antiproton collisions [17].…”

Section: "From the Change In Maximum Log-likelihood When The Full Dismentioning

confidence: 99%

Extraordinary claims: the 0.000029% solution

Dorigo

2015

EPJ Web of Conferences

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Abstract. The five-standard-deviation threshold is an established standard for discovery claims in experimental particle physics; however, the criterion is an ad-hoc recipe with no solid foundations. In this report I discuss its origins and the issues it was designed to address, pointing out its shortcomings and the need for a more flexible approach to decide when a new observed effect should be taken seriously.

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Lawrence P. Horwitz: Relativistic Quantum Mechanics

Reed

2017

Found Phys

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Measurement of the neutrino velocity with the OPERA detector in the CNGS beam using the 2012 dedicated data

Cited by 26 publications

References 8 publications

Theoretical particle limiting velocity from the bicubic equation: Neutrino example

Theoretical particle limiting velocity from the bicubic equation: Neutrino example

Extraordinary claims: the 0.000029% solution

Lawrence P. Horwitz: Relativistic Quantum Mechanics

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