S.I. Klimushin
Russian Academy of Sciences
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Astroparticle Physics | 1997
I. A. Belolaptikov; L. Bezrukov; B. A. Borisovets; N. M. Budnev; E. V. Bugaev; A. G. Chensky; I.A. Danilchenko; J.-A.M Djilkibaev; V. I. Dobrynin; G. V. Domogatsky; L.A. Donskych; A. A. Doroshenko; G. N. Dudkin; V.Yu. Egorov; S. V. Fialkovsky; A. A. Garus; A Gaponenko; A.V. Golikov; O. Gress; T.A Gress; M.N. Gushtan; R. Heller; V.B. Kabikov; H. Heukenkamp; A Karle; A. M. Klabukov; A.I Klimov; S.I. Klimushin; A. P. Koshechkin; J. Krabi
Abstract A first deep underwater detector for muons and neutrinos, NT-200 , is currently under construction in Lake Baikal. Part of the detector, NT-36 , with 36 photomultiplier tubes at three strings, has been installed in 1993. This array allowed for the first time a three-dimensional mapping of Cherenkov light deep underwater. Since then, various arrays have been almost continuously taking data. Presently a 96-PMT array is operating. We describe the NT-200 detector design and present results obtained with NT-36 .
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1999
R.I. Bagduev; V. Balkanov; I. A. Belolaptikov; L. Bezrukov; N. M. Budnev; B. A. Borisovets; G. V. Domogatsky; L.A. Donskych; A. A. Doroshenko; A. A. Garus; A.V. Golikov; B.M. Gluchovskoj; R. Heller; V.B. Kabikov; M.P. Khripunova; A. M. Klabukov; S.I. Klimushin; A. P. Koshechkin; L. A. Kuzmichov; G.V. Lisovski; B. K. Lubsandorzhiev; T. Mikolajski; Eh. A. Osipova; P. G. Pokhil; P. A. Pokolev; P.A. Putilov; Ch. Spiering; Z.I. Stepanenko; O. Streicher; T. Thon
A deep underwater Cherenkov telescope has been operating since 1993 in stages of growing size at 1.1 km depth in Lake Baikal. The key component of the telescope is the Optical Module (OM) which houses the highly sensitive phototube QUASAR-370. We describe design and parameters of the QUASAR-370, the layout of the optical module, the front-end electronics and the calibration procedures, and present selected results from the five-year operation underwater. Also, future developments with respect to a telescope consisting from several thousand OMs are discussed.
Astroparticle Physics | 1999
V. A. Balkanov; I. A. Belolaptikov; L. Bezrukov; N. M. Budnev; A. G. Chensky; I.A. Danilchenko; Zh.-A. M. Djilkibaev; G. V. Domogatsky; A. A. Doroshenko; S. V. Fialkovsky; O. N. Gaponenko; A. A. Garus; T.I. Gress; A. M. Klabukov; A. Klimov; S.I. Klimushin; A. P. Koshechkin; V. F. Kulepov; L. A. Kuzmichev; Vy. Kuznetzov; J.J. Laudinskaite; S.V. Lovtzov; B. K. Lubsandorzhiev; M. B. Milenin; R. R. Mirgazov; N. I. Moseiko; V.A. Netikov; Eh. A. Osipova; A. I. Panfilov; Yu. V. Parfenov
We present first neutrino induced events observed with a deep underwater neutrino telescope. Data from 70 days effective life time of the BAIKAL prototype telescope NT-96 have been analyzed with two different methods. With the standard track reconstruction method, 9 clear upward muon candidates have been identified, in good agreement with 8.7 events expected from Monte Carlo calculations for atmospheric neutrinos. The second analysis is tailored to muons coming from close to the opposite zenith. It yields 4 events, compared to 3.5 from Monte Carlo expectations. From this we derive a 90 % upper flux limit of 1.1 * 10^-13 cm^-2 sec^-1 for muons in excess of those expected from atmospheric neutrinos with zenith angle > 150 degrees and energy > 10GeV.We present neutrino induced events observed with a deep underwater neutrino telescope. Data from 70 days effective life time of the BAIKAL prototype telescope NT-96 have been analyzed with two different methods. With the standard track reconstruction method, 9 clear upward muon candidates have been identified, in good agreement with expectation from Monte Carlo calculations for atmospheric neutrinos. The second analysis is tailored to muons coming from close to the opposite zenith. It yields 4 events, compared to 3.5 from Monte Carlo expectations. From this we derive a 90% upper flux limit of 1:1 10 13 cm 2 sec 1 for muons in excess of those expected from atmospheric neutrinos with zenith angle > 150 degrees and energy > 10 GeV.Abstract We present the first neutrino induced events observed with a deep underwater neutrino telescope. Data from 70 days effective life time of the BAIKAL prototype telescope NT-96 have been analyzed with two different methods. With the standard track reconstruction method, 9 clear upward muon candidates have been identified, in good agreement with 8.7 events expected from Monte Carlo calculations for atmospheric neutrinos. The second analysis is tailored to muons coming from close to the opposite zenith. It yields 4 events, compared to 3.5 from Monte Carlo expectations. From this we derive a 90% upper flux limit of 1.1 · 10−13 cm−2 sec−1 for muons in excess of those expected from atmospheric neutrinos with zenith angle > 150 degrees and energy > 10 GeV.
Astroparticle Physics | 2000
V. Balkanov; I. A. Belolaptikov; L. Bezrukov; N. M. Budnev; A. G. Chensky; I. Danilchenko; Zh. A. M. Dzhilkibaev; G. V. Domogatsky; A. A. Doroshenko; S. V. Fialkovsky; O. N. Gaponenko; D. Kiss; A. M. Klabukov; A. Klimov; S.I. Klimushin; A. P. Koshechkin; Vy. Kuznetzov; V. F. Kulepov; L. Kuzmichev; J. Ljaudenskaite; S.V. Lovzov; B. K. Lubsandorzhiev; M. B. Milenin; R. R. Mirgazov; N. I. Moseiko; V.A. Netikov; E. Osipova; A. I. Panfilov; Yu. V. Parfenov; Alexander Anatolevich Pavlov
Abstract We present the results of a search for high-energy neutrinos with the Baikal underwater Cherenkov detector NT-96. An upper limit on the diffuse flux of ν e + ν μ + ν μ of E 2 Φ ν (E) −5 cm −2 s −1 sr −1 GeV within neutrino energy range 10 4 –10 7 GeV is obtained, assuming an E −2 behavior of the neutrino spectrum.
arXiv: Astrophysics | 2001
V. Balkanov; I. A. Belolaptikov; L. Bezrukov; N. M. Budnev; A. G. Chensky; I. Danilchenko; Zh. A. M. Dzhilkibaev; G. V. Domogatsky; A. A. Doroshenko; S. V. Fialkovsky; O. N. Gaponenko; O. Gress; D. Kiss; A. M. Klabukov; A. Klimov; S.I. Klimushin; A. P. Koshechkin; V. F. Kulepov; L. Kuzmichev; Vy. Kuznetzov; J. Ljaudenskaite; B. K. Lubsandorzhiev; M. B. Milenin; R. R. Mirgazov; N. I. Moseiko; V.A. Netikov; E. Osipova; A. I. Panfilov; Yu. V. Parfenov; L. Pankov
We review the present status of the Baikal Neutrino Project and present preliminary results of a search for upward going atmospheric neutrinos, WIMPs and magnetic monopoles obtained with the detector NT-2000 during 1998. Also the results of a search for very high energy neutrinos with partially completed detector in 1996 are presented.We review the present status of the Baikal Neutrino Project and present preliminary results of a search for upward going atmospheric neutrinos, WIMPs and magnetic monopoles obtained with the detector NT-2000 during 1998. Also the results of a search for very high energy neutrinos with partially completed detector in 1996 are presented.
International Journal of Modern Physics A | 2005
R. Wischnewski; V. Aynutdinov; V. Balkanov; I. A. Belolaptikov; N. M. Budnev; L. Bezrukov; A. G. Chensky; D. V. Chernov; I. Danilchenko; Zh. A. M. Dzhilkibaev; G. V. Domogatsky; A. Dyachok; S. V. Fialkovsky; O. N. Gaponenko; O. Gress; T. Gress; K. Kazakov; A. M. Klabukov; A. Klimov; S.I. Klimushin; K. Konischev; A. P. Koshechkin; L. Kuzmichev; V. F. Kulepov; Vy. Kuznetzov; B. K. Lubsandorzhiev; S. Mikheyev; M. B. Milenin; R. R. Mirgazov; E. Osipova
New results from the Baikal neutrino telescope NT200, based on the first 5 years of operation (1998–2003), are presented. We derive an all-flavor limit on the diffuse flux of astrophysical neutrinos between 20 TeV and 50 PeV, extract an enlarged sample of high energy muon neutrino events, and obtain limits on the flux of high energy atmospheric muons. In 2005, the upgraded telescope NT200+ will be commissioned: 3 additional distant strings with only 12 photo-multipliers each will rise the effective volume to 20 Mton at 10 PeV for this largest running neutrino telescope in the Northern hemisphere.
arXiv: Astrophysics | 2002
V. Balkanov; I. A. Belolaptikov; N. M. Budnev; L. Bezrukov; A. G. Chensky; I. Danilchenko; Zh. A. M. Dzhilkibaev; G. V. Domogatsky; S. Fialkovsky; O. N. Gaponenko; O. Gress; T. Gress; R. Il'yasov; D. Kiss; A. M. Klabukov; S.I. Klimushin; K. Konischev; A. P. Koshechkin; L. Kuzmichev; V. F. Kulepov; Vy. Kuznetzov; B. K. Lubsandorzhiev; R. R. Mirgazov; N. I. Moseiko; M. B. Milenin; E. Osipova; A. Pavlov; L. Pankov; A. I. Panfilov; E. Pliskovsky
We review the present status of the Baikal Neutrino Project and present the results obtained with the deep underwater neutrino telescope NT-200.We review the present status of the Baikal Neutrino Project and present the results obtained with the deep underwater neutrino telescope NT-200
Physics of Atomic Nuclei | 2000
V. A. Balkanov; I. A. Belolaptikov; L. Bezrukov; N. M. Budnev; A. G. Chensky; I. Danilchenko; Zh. A. M. Dzhilkibaev; G. V. Domogatsky; A. A. Doroshenko; S. V. Fialkovsky; O. N. Gaponenko; A. A. Garus; T. Gress; D. Kiss; A. Klimov; S.I. Klimushin; A. P. Koshechkin; Vy. Kuznetzov; V. F. Kulepov; L. A. Kuzmichev; S.V. Lovzov; J. J. Laudenskaite; B. K. Lubsandorzhiev; M. B. Milenin; R. R. Mirgazov; N. I. Moseiko; V.A. Netikov; E. Osipova; A. I. Panfilov; Yu. V. Parfenov
We review the present status of the Lake Baikal neutrino experiment and present selected physics results obtained during the consecutive stages of the stepwise upgrade of the detector: from NT-36 to NT-96. The results cover atmospheric muons, neutrino events, neutrinos of very high energy, searches for neutrino events from WIMP annihilation, searches for magnetic monopoles, and environmental studies. We also describe an air Cherenkov array developed for studying the angular resolution of NT-200.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2006
V. Aynutdinov; V. Balkanov; I. A. Belolaptikov; L. Bezrukov; D. Borschov; N. M. Budnev; I. Danilchenko; Ya. I. Davidov; G. V. Domogatsky; A. A. Doroshenko; A. Dyachok; Zh. A. M. Dzhilkibaev; S. V. Fialkovsky; O. N. Gaponenko; K. Golubkov; O. Gress; T. Gress; O. Grishin; A. M. Klabukov; A. Klimov; S.I. Klimushin; A. Kochanov; K. Konischev; A. P. Koshechkin; L. Kuzmichev; V. F. Kulepov; B. K. Lubsandorzhiev; S. Mikheyev; T. Mikolajski; M. B. Milenin
The Baikal Neutrino Telescope NT200 takes data since April 1998. On April 9th, 2005, the 10 Mton scale detector NT200
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2003
V. Balkanov; I. A. Belolaptikov; L. Bezrukov; N. M. Budnev; A. Capone; A. G. Chensky; I. Danilchenko; G. V. Domogatsky; Zh. A. M. Dzhilkibaev; S. V. Fialkovsky; O. N. Gaponenko; O. Gress; T. Gress; R. Il'yasov; A. M. Klabukov; A. Klimov; S.I. Klimushin; K. Konischev; A. P. Koshechkin; Vy. Kuznetzov; L. A. Kuzmichev; V. F. Kulepov; B. K. Lubsandorzhiev; R. Masullo; E. Migneco; S. Mikheyev; M. B. Milenin; R. R. Mirgazov; N. I. Moseiko; E. Osipova
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