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Nötrinonun Elektromagnetik Özellikleri

Electromagnetic Properties of the Neutrino

Journal Name:

  • Karaelmas Fen ve Mühendislik Dergisi

Publication Year:

  • 2011

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
In this paper, we have discussed the electromagnetic properties of Dirac and Majorana neutrinos. The effective lagrangian method which is crucial for physics beyond the standard model, is explained briefly. We have analysed two different effective lagrangians that allow neutrino photon interactions.
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Abstract (Original Language): 
Bu çalışmada, Dirac ve Majorana nötrinolarının elektromagnetik özellikleri tartışılmıştır. Standart model ötesi fiziğin araştırılmasında önemli bir yeri olan efektif lagranjiyen yöntemi kısaca açıklanmış ve bu yöntemde nötrinoların fotonla etkileşimine olanak sağlayan iki farklı efektif lagranjiyen incelenmiştir
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  • Turkish

REFERENCES

References: 

Apollonio, M., Baldini, A., Bemporad, C., Caffau,
E., Cei, F., Déclais, Y., de Kerret, H., Dieterle, B.,
Etenko, A., George, J., Giannini, G., Grassi, M.,
Kozlov, Y., Kropp, W., Kryn, D., Laiman, M.,
Lane, CE., Lefièvre, B., Machulin, I.,
Martemyanov, A., Martemyanov, V., Mikaelyan,
L., Nicolò, D., Obolensky, M., Pazzi, R., Pieri,
G., Price, L., Riley, S., Reeder, R., Sabelnikov,
A., Santin, G., Skorokhvatov, M., Sobel, H.,
Steele, J., Steinberg, R., Sukhotin, S., Tomshaw,
S., Veron, D., Vyrodov, V. 1998. Initial results
from the CHOOZ long baseline reactor neutrino
oscillation experiment. Phys. Lett. B, 420: 397-404.
Athanassopoulos, C., Auerbach LB., Bauer, D.,
Bolton, RD., Burman, RL., Cohen, I., Caldwell,
DO., Dieterle, BD., Donahue, JB., Eisner, AM.,
Fazely A., Federspiel FJ., Garvey, GT., Gray M.,
Gunasingha, RM., Highland, V., Imlay, R.,
Johnston, K., Kim, HJ., Louis, WC., Lu, A.,
Margulies, J., Mills, GB., McIlhany, K., Metcalf,
W., Reeder, RA., Sandberg, V., Schillaci, M.,
Smith, D., Stancu, I., Strossman, W., Tayloe, R.,
VanDalen, GJ., Vernon, W., Wang, YX., White,
DH., Whitehouse, D., Works, D., Xiao, Y., Yellin,
S. 1997. The liquid scintillator neutrino detector
and LAMPF neutrino source. Nucl. Instrum.
Methods A, 388: 149-172.
Armbruster, B., Eberhard, V., Eichner, C., Eitel, K.,
Gemmeke, H., Grandegger, W., Hunkel, D.,
Jannakos, T., Kleifges, M., Kleinfeller, J.,
Plischke, P., Rapp, J., Weber, J., Wochele, J.,
Wolf, J., Wölfle, S., Zeitnitz, B., Bodmann, B.,
Ferstl, M., Finckh, E., Hanika, T., Hehle, M.,
Hößl, J., Kretschmer, W., Schmidt, H., Stumm,
O., Maschuw, R., Edgington, JA., Seligmann, B.,
Dodd, AC., Booth, NE. 1994. KARMEN: neutrino
physics at ISIS. Prog. Nucl. Part. Phys., 32: 351-373.
Babu, KS., Mathur, VS. 1987. Magnetic moments of
Dirac and Majorana neutrinos. Phys. Lett. B, 196:
218-222.
Bell, NF., Cirigliano, V., Ramsey-Musolf, MJ.,
Vogel, P., Wise, MB. 2005. How Magnetic is the
Dirac Neutrino?. Phys. Rev. Lett. 95: 151802-06.
Bemporad, C., Gratta, G., Vogel, P. 2002. Reactorbased
neutrino oscillation experiments. Rev. Mod.
Phys., 74: 297-328.
Bennett, CL., Hill, RS., Hinshaw, G., Notla, MR.,
Odegard, N., Page, L., Spergel, DN., Weiland,
JL., Wright, EL., Halpern, M., Jarosik, N., Kogut,
A., Limon, M., Meyer, SS., Tucker, GS.,
Wollack, E. 2003. First Year Wilkinson
Microwave Anisotropy Probe (WMAP)
Observations: Determination of Cosmological
Parameters. Astrophys. J. Suppl. 148:175-194.
Boehm, F., Busenitz, J., Cook, B., Gratta, G.,
Henrikson, H., Kornis, J., Lawrence, D., Lee,
KB., McKinny, K., Miller, L., Novikov, V.,
Piepke, A., Ritchie, B., Tracy, D., Vogel, P.,
Wang, YF., Wolf, J. 2001. Final results from the
Palo Verde neutrino oscillation experiment. Phys.
Rev. D, 64: 112001-10.
Buchmüller, W., Wyler, D. 1986. Effective
lagrangian analysis of new interactions and
flavour conservation. Nuclear Physics, B, 268: 621-
653.
Cowsik, R., McClelland, J. 1972. An Upper Limit on
the Neutrino Rest Mass. Phys. Rev. Lett., 29: 669-
670.
Drexlin, G. 1994. KARMEN: neutrino physics at
ISIS. Prog. Nucl. Part. Phys., 32: 351-373.
Fukugida, M., Yanagida, T. 1987. Particle-physics
model for Voloshin-Vysotsky-Okun solution to
the solar-neutrino problem. Phys. Rev. Lett., 58:
1807-1809.
Ghosh, RK. 1984. Study of the decay j i    .
Phys. Rev. D, 29: 493-501.
Gninenko, SN., Krasnikov, NV. 1999. Limits on the
magnetic moment of sterile neutrino and twophoton
neutrino decay. Phys. Lett. B, 450: 165-172.
Kim, CW., Pevsner, A. 1993. Massive Neutrinos in
Physics and Astrophysics, Harwood Academic,
USA, 247 s.
Larios, F., Martínez R., Pérez, MA. 1995. Constraints
on i j    from  e ,  ,e . Phys.
Lett. B, 345: 259-262.
Lee, BW., Shrock, RE. 1977. Natural suppression of
symmetry violation in gauge theories: Muon- and
electron-lepton-number nonconservation. Phys.
Rev. D, 16: 1444-1473.
Liu, J. 1991. Low energy neutrino-two-photon
interactions. Phys. Rev. D, 44: 2879- 2891.
Marciano, WJ., Sanda, AI. 1977. Exotic decays of the
muon and heavy leptons in gauge theories. Phys.
Lett. B, 67: 303-305.
Maya, M., Pérez, A., Tavares-Velasco, G., Vega, B.
1998. A direct constraint on dimension-eight
operators from Z  . Phys. Lett. B, 434: 354-
357.
Nieves, JF. 1983. Two photon decay of heavy
neutrinos. Phys. Rev. D, 28: 1664-1670.
Pal, PB. 1992. Particle physics confronts the solar
neutrıno problem. Int. J. Mod. Phys. A, 7: 5387-
5460.
Piepke, A. 2001. KamLAND: A reactor neutrino
experiment testing the solar neutrino anomaly.
Nucl. Phys. B (Proc. Suppl.), 91: 99-104.

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