T. V. Knodel
Russian Academy of Sciences
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Featured researches published by T. V. Knodel.
Physical Review C | 1999
J. N. Abdurashitov; V. N. Gavrin; S. V. Girin; V. V. Gorbachev; T. V. Ibragimova; A. V. Kalikhov; N. G. Khairnasov; T. V. Knodel; I. N. Mirmov; A. A. Shikhin; E. P. Veretenkin; V. M. Vermul; V. E. Yants; G. T. Zatsepin; T. J. Bowles; W. A. Teasdale; D. L. Wark; Michael L. Cherry; Jeffrey S. Nico; B. T. Cleveland; Raymond Davis; K. Lande; P. Wildenhain; S. R. Elliott; J. F. Wilkerson
The solar neutrino capture rate measured by the Russian-American Gallium Experiment (SAGE) on metallic gallium during the period January 1990 through December 1997 is 67.2 (+7.2-7.0) (+3.5-3.0) SNU, where the uncertainties are statistical and systematic, respectively. This represents only about half of the predicted Standard Solar Model rate of 129 SNU. All the experimental procedures, including extraction of germanium from gallium, counting of 71Ge, and data analysis are discussed in detail.
Journal of Experimental and Theoretical Physics | 2002
J. N. Abdurashitov; E P. Veretenkin; V. M. Vermul; V. N. Gavrin; S. V. Girin; V. V. Gorbachev; P P. Gurkina; G. T. Zatsepin; T. V. Ibragimova; A. V. Kalikhov; T. V. Knodel; I. N. Mirmov; N. G. Khairnasov; A. A. Shikhin; V. E. Yants; T. J. Bowles; W A. Teasdale; Jeffrey S. Nico; J. F. Wilkerson; B T. Cleveland; Stephen R. Elliott
We present the results of measurements of the solar neutrino capture rate in gallium metal by the Russian-American Gallium Experiment SAGE during slightly more than half of a 22-year cycle of solar activity. Combined analysis of the data of 92 runs during the 12-year period January 1990 through December 2001 gives a capture rate of solar neutrinos with energy more than 233 keV of 70.8 +5.3/-5.2 (stat.) +3.7/-3.2 (syst.) SNU. This represents only slightly more than half of the predicted standard solar model rate of 128 SNU. We give the results of new runs beginning in April 1998 and the results of combined analysis of all runs since 1990 during yearly, monthly, and bimonthly periods. Using a simple analysis of the SAGE results combined with those from all other solar neutrino experiments, we estimate the electron neutrino pp flux that reaches the Earth to be (4.6 +/- 1.1) E10/(cm^2-s). Assuming that neutrinos oscillate to active flavors the pp neutrino flux emitted in the solar fusion reaction is approximately (7.7 +/- 1.8) E10/(cm^2-s), in agreement with the standard solar model calculation of (5.95 +/- 0.06) E10/(cm^2-s).We present measurements of the solar neutrino capture rate on metallic gallium in the Soviet-American gallium experiment (SAGE) over a period of slightly more than half the 22-year solar cycle. A combined analysis of 92 runs over the twelve-year period from January 1990 until December 2001 yields a capture rate of 70.8−5.2+5.3 (stat)−3.2+3.7 (sys) SNU for solar neutrinos with energies above 0.233 MeV. This value is slightly more than half the rate predicted by the standard solar model, 130 SNU. We present the results of new runs since April 1998 and analyze all runs combined by years, months, and bimonthly periods beginning in 1990. A simple analysis of the SAGE results together with the results of other solar neutrino experiments gives an estimate of (4.6±1.2)× 1010 neutrinos cm−2 s−1 for the flux of the electron pp neutrinos that reach the Earth without changing their flavor. The flux of the pp neutrinos produced in thermonuclear reactions in the Sun is estimated to be (7.6 ± 2.0) × 1010 neutrinos cm−2 s−1, in agreement with the value of (5.95±0.06)×1010 neutrinos cm−2 s−1 predicted by the standard solar model.
Physical Review C | 2009
J. N. Abdurashitov; V. N. Gavrin; V. V. Gorbachev; P. P. Gurkina; T. V. Ibragimova; A. V. Kalikhov; N. G. Khairnasov; T. V. Knodel; I. N. Mirmov; A. A. Shikhin; E. P. Veretenkin; V. E. Yants; G. T. Zatsepin; T. J. Bowles; S. R. Elliott; W. A. Teasdale; Jeffrey S. Nico; B. T. Cleveland; J. F. Wilkerson
The Russian-American experiment SAGE began to measure the solar neutrino capture rate with a target of gallium metal in December 1989. Measurements have continued with only a few brief interruptions since that time. In this article we present the experimental improvements in SAGE since its last published data summary in December 2001. Assuming the solar neutrino production rate was constant during the period of data collection, combined analysis of 168 extractions through December 2007 gives a capture rate of solar neutrinos with energy more than 233 keV of
Physics Letters B | 1994
J. N. Abdurashitov; E. L. Faizov; V. N. Gavrin; A.O. Gusev; A. V. Kalikhov; T. V. Knodel; I. I. Knyshenko; V. N. Kornoukhov; I. N. Mirmov; A.M. Pshukov; A.M. Shalagin; A. A. Shikhin; P. V. Timofeyev; E. P. Veretenkin; V. M. Vermul; G. T. Zatsepin; T. J. Bowles; J.S. Nico; W. A. Teasdale; D.L. Wark; J.F. Wilkerson; B.T. Cleveland; T. Daily; Raymond Davis; K. Lande; C.K. Lee; P.W. Wildenhain; S.R. Elliott; Michael L. Cherry; R.T. Kouzes
65.{4}_{\ensuremath{-}3.0}^{+3.1}
Physical Review C | 1998
J. N. Abdurashitov; V. V. Gorbachev; V. N. Gavrin; A. V. Zvonarev; I. N. Mirmov; John F. Wilkerson; B T. Cleveland; V. N. Kornoukhov; R. Davis; V. E. Yants; A. V. Kalikhov; Tatiana V. Ibragimova; W. A. Teasdale; Jeffrey S. Nico; V.N. Karaulov; A. A. Shikhin; E. P. Veretenkin; Yu. S. Khomyakov; D.L. Wark; K. Lande; S. R. Elliott; T.J. Bowels; V.I. Maev; V. S. Shkol'nik; C. K. Lee; N. V. Skorikov; T. Daily; V. M. Vermul; V.L. Levitin; P.I. Nazarenko
(stat)
Physical Review C | 1999
J. N. Abdurashitov; V. N. Gavrin; S. V. Girin; V. V. Gorbachev; T. V. Ibragimova; A. V. Kalikhov; N. G. Khairnasov; T. V. Knodel; V. N. Kornoukhov; I. N. Mirmov; A. A. Shikhin; E. P. Veretenkin; V. M. Vermul; V. E. Yants; G. T. Zatsepin; Yu. S. Khomyakov; A. V. Zvonarev; T. J. Bowles; J.S. Nico; W. A. Teasdale; D.L. Wark; Michael L. Cherry; V.N. Karaulov; V.L. Levitin; V.I. Maev; P.I. Nazarenko; V. S. Shkol’nik; N. V. Skorikov; B. T. Cleveland; T. Daily
{}_{\ensuremath{-}2.8}^{+2.6}
Physical Review C | 2006
J. N. Abdurashitov; V. I. Barsanov; T. J. Bowles; B. T. Cleveland; S. R. Elliott; V. N. Gavrin; S. V. Girin; V. V. Gorbachev; P. P. Gurkina; W. C. Haxton; T. V. Ibragimova; A. A. Janelidze; A. V. Kalikhov; A.I. Karpenko; N. G. Khairnasov; Yu. S. Khomyakov; T. V. Knodel; A. V. Korenkova; N. A. Kotelnikov; K. Lande; V.V. Maltsev; S. Yu. Markov; V. A. Matveev; I. N. Mirmov; O.V. Mishin; Jeffrey S. Nico; N.N. Oshkanov; V.M. Poplavsky; A. N. Petrov; V. V. Popov
(syst) SNU. The weighted average of the results of all three Ga solar neutrino experiments, SAGE, Gallex, and GNO, is now
Nuclear Physics B (Proceedings Supplements) | 1991
A. I. Abazov; D. N. Abdurashitov; O. L. Anosov; L. A. Eroshkina; E. L. Faizov; V. N. Gavrin; A. V. Kalikhov; T. V. Knodel; I. I. Knyshenko; V. N. Kornoukhov; S. A. Mezentseva; I. N. Mirmov; A. I. Ostrinsky; V. V. Petukhov; A.M. Pshukov; N. Ye Revzin; A. A. Shikhin; P. V. Timofeyev; E. P. Veretenkin; V. M. Vermul; Yu. Zakharov; G. T. Zatsepin; V.I. Zhandarov; T. J. Bowles; B. T. Cleveland; S. R. Elliott; H.A. O'Brien; D.L. Wark; J.F. Wilkerson; Raymond Davis
66.1\ifmmode\pm\else\textpm\fi{}3.1
Nuclear Physics B (Proceedings Supplements) | 1994
V. N. Gavrin; E. L. Faizov; A. V. Kalikhov; T. V. Knodel; I. I. Knyshenko; V. N. Kornoukhov; I. N. Mirmov; A.V. Ostrinsky; A.M. Pshukov; A. A. Shikhin; P. V. Timofeyev; E. P. Veretenkin; V. M. Vermul; G. T. Zatsepin; T. J. Bowles; S. R. Elliott; J.S. Nico; W. A. Teasdale; D.L. Wark; J.F. Wilkerson; B.T. Cleveland; T. Daily; Richard Davis; K. Lande; C. K. Lee; P. Wildenhain; Michael L. Cherry; R.T. Kouzes
SNU, where statistical and systematic uncertainties have been combined in quadrature. During the recent period of data collection a new test of SAGE was made with a reactor-produced
Annals of the New York Academy of Sciences | 1993
O. L. Anosov; T. J. Bowles; Michael L. Cherry; B.T. Cleveland; Richard Davis; S. R. Elliott; E. L. Faizov; V. N. Gavrin; A. V. Kalikhov; T. V. Knodel; I. I. Knyshenko; V. N. Kornoukhov; R.T. Kouzes; K. Lande; I.N. Miromov; J.S. Nico; H.A. O'brien; A.V. Ostrinsky; A.M. Pshukov; A. A. Shikhin; P. V. Timofeyev; E. P. Veretenkin; V. M. Vermul; D.L. Wark; J.F. Wilkerson; G. T. Zatsepin
^{37}\mathrm{Ar}
