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Your search keyword '"Gurentsov, V. I."' showing total 43 results
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43 results on '"Gurentsov, V. I."'

1. Development of MMC-based lithium molybdate cryogenic calorimeters for AMoRE-II

Author

Agrawal, A., Alenkov, V. V., Aryal, P., Bae, H., Beyer, J., Bhandari, B., Boiko, R. S., Boonin, K., Buzanov, O., Byeon, C. R., Chanthima, N., Cheoun, M. K., Choe, J. S., Choi, S., Choudhury, S., Chung, J. S., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gavrilyuk, Y. M., Gezhaev, A. M., Gileva, O., Grigorieva, V. D., Gurentsov, V. I., Ha, C., Ha, D. H., Ha, E. J., Hwang, D. H., Jeon, E. J., Jeon, J. A., Jo, H. S., Kaewkhao, J., Kang, C. S., Kang, W. G., Kazalov, V. V., Kempf, S., Khan, A., Khan, S., Kim, D. Y., Kim, G. W., Kim, H. B., Kim, H. J., Kim, H. L., Kim, H. S., Kim, M. B., Kim, S. C., Kim, S. K., Kim, S. R., Kim, W. T., Kim, Y. D., Kim, Y. H., Kirdsiri, K., Ko, Y. J., Kobychev, V. V., Kornoukhov, V., Kuzminov, V. V., Kwon, D. H., Lee, C. H., Lee, D. Y., Lee, E. K., Lee, H. J., Lee, H. S., Lee, J., Lee, J. Y., Lee, K. B., Lee, M. H., Lee, M. K., Lee, S. W., Lee, Y. C., Leonard, D. S., Lim, H. S., Mailyan, B., Makarov, E. P., Nyanda, P., Oh, Y., Olsen, S. L., Panasenko, S. I., Park, H. K., Park, H. S., Park, K. S., Park, S. Y., Polischuk, O. G., Prihtiadi, H., Ra, S., Ratkevich, S. S., Rooh, G., Sari, M. B., Seo, J., Seo, K. M., Sharma, B., Shin, K. A., Shlegel, V. N., Siyeon, K., So, J., Sokur, N. V., Son, J. K., Song, J. W., Srisittipokakun, N., Tretyak, V. I., Wirawan, R., Woo, K. R., Yeon, H. J., Yoon, Y. S., and Yue, Q.

Subjects
Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment, Nuclear Experiment
Abstract

The AMoRE collaboration searches for neutrinoless double beta decay of $^{100}$Mo using molybdate scintillating crystals via low temperature thermal calorimetric detection. The early phases of the experiment, AMoRE-pilot and AMoRE-I, have demonstrated competitive discovery potential. Presently, the AMoRE-II experiment, featuring a large detector array with about 90 kg of $^{100}$Mo isotope, is under construction.This paper discusses the baseline design and characterization of the lithium molybdate cryogenic calorimeters to be used in the AMoRE-II detector modules. The results from prototype setups that incorporate new housing structures and two different crystal masses (316 g and 517 - 521 g), operated at 10 mK temperature, show energy resolutions (FWHM) of 7.55 - 8.82 keV at the 2.615 MeV $^{208}$Tl $\gamma$ line, and effective light detection of 0.79 - 0.96 keV/MeV. The simultaneous heat and light detection enables clear separation of alpha particles with a discrimination power of 12.37 - 19.50 at the energy region around $^6$Li(n, $\alpha$)$^3$H with Q-value = 4.785 MeV. Promising detector performances were demonstrated at temperatures as high as 30 mK, which relaxes the temperature constraints for operating the large AMoRE-II array.

Published
2024

2. Improved limit on neutrinoless double beta decay of $^{100}$Mo from AMoRE-I

Author

Agrawal, A., Alenkov, V. V., Aryal, P., Beyer, J., Bhandari, B., Boiko, R. S., Boonin, K., Buzanov, O., Byeon, C. R., Chanthima, N., Cheoun, M. K., Choe, J. S., Choi, Seonho, Choudhury, S., Chung, J. S., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gavrilyuk, Y. M., Gezhaev, A. M., Gileva, O., Grigorieva, V. D., Gurentsov, V. I., Ha, C., Ha, D. H., Ha, E. J., Hwang, D. H., Jeon, E. J., Jeon, J. A., Jo, H. S., Kaewkhao, J., Kang, C. S., Kang, W. G., Kazalov, V. V., Kempf, S., Khan, A., Khan, S., Kim, D. Y., Kim, G. W., Kim, H. B., Kim, Ho-Jong, Kim, H. J., Kim, H. L., Kim, H. S., Kim, M. B., Kim, S. C., Kim, S. K., Kim, S. R., Kim, W. T., Kim, Y. D., Kim, Y. H., Kirdsiri, K., Ko, Y. J., Kobychev, V. V., Kornoukhov, V., Kuzminov, V. V., Kwon, D. H., Lee, C. H., Lee, DongYeup, Lee, E. K., Lee, H. J., Lee, H. S., Lee, J., Lee, J. Y., Lee, K. B., Lee, M. H., Lee, M. K., Lee, S. W., Lee, Y. C., Leonard, D. S., Lim, H. S., Mailyan, B., Makarov, E. P., Nyanda, P., Oh, Y., Olsen, S. L., Panasenko, S. I., Park, H. K., Park, H. S., Park, K. S., Park, S. Y., Polischuk, O. G., Prihtiadi, H., Ra, S., Ratkevich, S. S., Rooh, G., Sari, M. B., Seo, J., Seo, K. M., Sharma, B., Shin, K. A., Shlegel, V. N., Siyeon, K., So, J., Sokur, N. V., Son, J. K., Song, J. W., Srisittipokakun, N., Tretyak, V. I., Wirawan, R., Woo, K. R., Yeon, H. J., Yoon, Y. S., and Yue, Q.

Subjects
Nuclear Experiment, High Energy Physics - Experiment
Abstract

AMoRE searches for the signature of neutrinoless double beta decay of $^{100}$Mo with a 100 kg sample of enriched $^{100}$Mo. Scintillating molybdate crystals coupled with a metallic magnetic calorimeter operate at milli-Kelvin temperatures to measure the energy of electrons emitted in the decay. As a demonstration of the full-scale AMoRE, we conducted AMoRE-I, a pre-experiment with 18 molybdate crystals, at the Yangyang Underground Laboratory for over two years. The exposure was 8.02 kg$\cdot$year (or 3.89 kg$_{\mathrm{^{100}Mo}}\cdot$year) and the total background rate near the Q-value was 0.025 $\pm$ 0.002 counts/keV/kg/year. We observed no indication of $0\nu\beta\beta$ decay and report a new lower limit of the half-life of $^{100}$Mo $0\nu\beta\beta$ decay as $ T^{0\nu}_{1/2}>3.0\times10^{24}~\mathrm{years}$ at 90\% confidence level. The effective Majorana mass limit range is $m_{\beta\beta}<$(210--610) meV using nuclear matrix elements estimated in the framework of different models, including the recent shell model calculations., Comment: 8 pages, 5 figures

Published
2024

3. Projected background and sensitivity of AMoRE-II

Author

Agrawal, A., Alenkov, V. V., Aryal, P., Beyer, J., Bhandari, B., Boiko, R. S., Boonin, K., Buzanov, O., Byeon, C. R., Chanthima, N., Cheoun, M. K., Choe, J. S., Choi, Seonho, Choudhury, S., Chung, J. S., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gavrilyuk, Y. M., Gezhaev, A. M., Gileva, O., Grigorieva, V. D., Gurentsov, V. I., Ha, C., Ha, D. H., Ha, E. J., Hwnag, D. H., Jeon, E. J., Jeon, J. A., Jo, H. S., Kaewkhao, J., Kang, C. S., Kang, W. G., Kazalov, V. V., Kempf, S., Khan, A., Khan, S., Kim, D. Y., Kim, G. W., Kim, H. B., Kim, Ho-Jong, Kim, H. J., Kim, H. L., Kim, H. S., Kim, M. B., Kim, S. C., Kim, S. K., Kim, S. R., Kim, W. T., Kim, Y. D., Kim, Y. H., Kirdsiri, K., Ko, Y. J., Kobychev, V. V., Kuzminov, V. Kornoukhov V. V., Kwon, D. H., Lee, C. H., Lee, D. Y., Lee, E. K., Lee, H. J., Lee, H. S., Lee, J., Lee, J. Y., Lee, K. B., Lee, M. H., Lee, M. K., Lee, S. W., Lee, Y. C., Leonard, D. S., Lim, H. S., Mailyan, B., Makarov, E. P., Nyanda, P., Oh, Y., Olsen, S. L., Panasenko, S. I., Park, H. K., Park, H. S., Park, K. S., Park, S. Y., Polischuk, O. G., Prihtiadi, H., Ra, S., Rooh, S. S. Ratkevich G., Sari, M. B., Seo, J., Seo, K. M., Sharma, B., Shin, K. A., Shlegel, V. N., Siyeon, K., So, J., Sokur, N. V., Son, J. K., Song, J. W., Srisittipokakun, N., Tretyak, V. I., Wirawan, R., Woo, K. R., Yeon, H. J., Yoon, Y. S., and Yue, Q.

Subjects
Physics - Instrumentation and Detectors, High Energy Physics - Experiment
Abstract

AMoRE-II aims to search for neutrinoless double beta decay with an array of 423 Li$_2$$^{100}$MoO$_4$ crystals operating in the cryogenic system as the main phase of the Advanced Molybdenum-based Rare process Experiment (AMoRE). AMoRE has been planned to operate in three phases: AMoRE-pilot, AMoRE-I, and AMoRE-II. AMoRE-II is currently being installed at the Yemi Underground Laboratory, located approximately 1000 meters deep in Jeongseon, Korea. The goal of AMoRE-II is to reach up to $T^{0\nu\beta\beta}_{1/2}$ $\sim$ 6 $\times$ 10$^{26}$ years, corresponding to an effective Majorana mass of 15 - 29 meV, covering all the inverted mass hierarchy regions. To achieve this, the background level of the experimental configurations and possible background sources of gamma and beta events should be well understood. We have intensively performed Monte Carlo simulations using the GEANT4 toolkit in all the experimental configurations with potential sources. We report the estimated background level that meets the 10$^{-4}$counts/(keV$\cdot$kg$\cdot$yr) requirement for AMoRE-II in the region of interest (ROI) and show the projected half-life sensitivity based on the simulation study.

Published
2024

4. Background study of the AMoRE-pilot experiment

Author

Agrawal, A., Alenkov, V. V., Aryal, P., Beyer, J., Bhandari, B., Boiko, R. S., Boonin, K., Buzanov, O., Byeon, C. R., Chanthima, N., Cheoun, M. K., Choe, J. S., Choi, Seonho, Choudhury, S., Chung, J. S., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gavrilyuk, Yu. M., Gezhaev, A. M., Gileva, O., Grigorieva, V. D., Gurentsov, V. I., Ha, C., Ha, D. H., Ha, E. J., Hwang, D. H., Jeon, E. J., Jeon, J. A., Jo, H. S., Kaewkhao, J., Kang, C. S., Kang, W. G., Kazalov, V. V., Kempf, S., Khan, A., Khan, S., Kim, D. Y., Kim, G. W., Kim, H. B., Kim, Ho-Jong, Kim, H. J., Kim, H. L., Kim, H. S., Kim, M. B., Kim, S. C., Kim, S. K., Kim, S. R., Kim, W. T., Kim, Y. D., Kim, Y. H., Kirdsiri, K., Ko, Y. J., Kobychev, V. V., Kornoukhov, V., Kuzminov, V. V., Kwon, D. H., Lee, C. H., Lee, DongYeup, Lee, E. K., Lee, H. J., Lee, H. S., Lee, J., Lee, J. Y., Lee, K. B., Lee, M. H., Lee, M. K., Lee, S. W., Lee, Y. C., Leonard, D. S., Lim, H. S., Mailyan, B., Makarov, E. P., Nyanda, P., Oh, Y., Olsen, S. L., Panasenko, S. I., Park, H. K., Park, H. S., Park, K. S., Park, S. Y., Polischuk, O. G., Prihtiadi, H., Ra, S., Ratkevich, S. S., Rooh, G., Sari, M. B., Seo, J., Seo, K. M., Sharma, B., Shin, K. A., Shlegel, V. N., Siyeon, K., So, J., Sokur, N. V., Son, J. K., Song, J. W., Srisittipokakun, N., Tretyak, V. I., Wirawan, R., Woo, K. R., Yeon, H. J., Yoon, Y. S., and Yue, Q.

Subjects
Nuclear Experiment, High Energy Physics - Experiment
Abstract

We report a study on the background of the Advanced Molybdenum-Based Rare process Experiment (AMoRE), a search for neutrinoless double beta decay (\znbb) of $^{100}$Mo. The pilot stage of the experiment was conducted using $\sim$1.9 kg of \CAMOO~ crystals at the Yangyang Underground Laboratory, South Korea, from 2015 to 2018. We compared the measured $\beta/\gamma$ energy spectra in three experimental configurations with the results of Monte Carlo simulations and identified the background sources in each configuration. We replaced several detector components and enhanced the neutron shielding to lower the background level between configurations. A limit on the half-life of $0\nu\beta\beta$ decay of $^{100}$Mo was found at $T_{1/2}^{0\nu} \ge 3.0\times 10^{23}$ years at 90\% confidence level, based on the measured background and its modeling. Further reduction of the background rate in the AMoRE-I and AMoRE-II are discussed.

Published
2024

7. First Results from the AMoRE-Pilot neutrinoless double beta decay experiment

Author

Alenkov, V., Bae, H. W., Beyer, J., Boiko, R. S., Boonin, K., Buzanov, O., Chanthima, N., Cheoun, M. K., Chernyak, D. M., Choe, J. S., Choi, S., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gavriljuk, Yu. M., Gezhaev, A. M., Grigoryeva, V. D., Gurentsov, V. I., Gylova, O., Ha, C., Ha, D. H., Ha, E. J., Hahn, I. S., Jang, C. H., Jeon, E. J., Jeon, J. A., Jo, H. S., Kaewkhao, J., Kang, C. S., Kang, S. J., Kang, W. G., Kazalov, V. V., Khan, A., Khan, S., Kim, D. Y., Kim, G. W., Kim, H. B., Kim, H. J., Kim, H. L., Kim, H. S., Kim, I., Kim, S. C., Kim, S. G., Kim, S. K., Kim, S. R., Kim, W. T., Kim, Y. D., Kim, Y. H., Kirdsiri, K., Ko, Y. J., Kobychev, V. V., Kornoukhov, V., Kuzminov, V. V., Kwon, D. H., Lee, C., Lee, E. K., Lee, H. J., Lee, H. S., Lee, J. S., Lee, J. Y., Lee, K. B., Lee, M. H., Lee, M. K., Lee, S. W., Lee, S. H., Leonard, D., Li, J., Li, Y., Limkitjaroenporn, P., Makarov, E. P., Oh, S. Y., Oh, Y. M., Olsen, S. L., Pabitra, A., Panasenko, S. I., Pandey, I., Park, C. W., Park, H. K., Park, H. S., Park, K. S., Park, S. Y., Poda, D. V., Polischuk, O. G., Prihtiadi, H., Ra, S. J., Ratkevich, S. S., Rooh, G., Sari, M. B., Seo, K. M., Shin, J. W., Shin, K. A., Shlegel, V. N., Siyeon, K., So, J. H., Son, J. K., Srisittipokakun, N., Sujita, K., Tretyak, V. I., Wirawan, R., Woo, K. R., Yoon, Y. S., Yue, Q., and Zaman, S. U.

Subjects
High Energy Physics - Experiment, Physics - Instrumentation and Detectors
Abstract

The Advanced Molybdenum-based Rare process Experiment (AMoRE) aims to search for neutrinoless double beta decay (0$\nu\beta\beta$) of $^{100}$Mo with $\sim$100 kg of $^{100}$Mo-enriched molybdenum embedded in cryogenic detectors with a dual heat and light readout. At the current, pilot stage of the AMoRE project we employ six calcium molybdate crystals with a total mass of 1.9 kg, produced from $^{48}$Ca-depleted calcium and $^{100}$Mo-enriched molybdenum ($^{48\textrm{depl}}$Ca$^{100}$MoO$_4$). The simultaneous detection of heat(phonon) and scintillation (photon) signals is realized with high resolution metallic magnetic calorimeter sensors that operate at milli-Kelvin temperatures. This stage of the project is carried out in the Yangyang underground laboratory at a depth of 700 m. We report first results from the AMoRE-Pilot $0\nu\beta\beta$ search with a 111 kg$\cdot$d live exposure of $^{48\textrm{depl}}$Ca$^{100}$MoO$_4$ crystals. No evidence for $0\nu\beta\beta$ decay of $^{100}$Mo is found, and a upper limit is set for the half-life of 0$\nu\beta\beta$ of $^{100}$Mo of $T^{0\nu}_{1/2} > 9.5\times10^{22}$ y at 90% C.L.. This limit corresponds to an effective Majorana neutrino mass limit in the range $\langle m_{\beta\beta}\rangle\le(1.2-2.1)$ eV.

Published
2019
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8. Radioassay of the materials for AMoRE-II experiment

Author

Agrawal, A., primary, Alenkov, V. V., additional, Aryal, P., additional, Bae, H., additional, Beyer, J., additional, Bhandari, B., additional, Boiko, R. S., additional, Boonin, K., additional, Buzanov, O., additional, Byeon, C. R., additional, Chanthima, N., additional, Cheoun, M. K., additional, Choe, J. S., additional, Choi, S., additional, Choudhury, S., additional, Chung, J. S., additional, Danevich, F. A., additional, Djamal, M., additional, Drung, D., additional, Enss, C., additional, Fleischmann, A., additional, Gangapshev, A. M., additional, Gastaldo, L., additional, Gavrilyuk, Y. M., additional, Gezhaev, A. M., additional, Gileva, O., additional, Grigorieva, V. D., additional, Gurentsov, V. I., additional, Ha, C., additional, Ha, D. H., additional, Ha, E. J., additional, Hwang, D. H., additional, Jeon, E. J., additional, Jeon, J. A., additional, Jo, H. S., additional, Kaewkhao, J., additional, Kang, C. S., additional, Kang, W. G., additional, Kazalov, V. V., additional, Kempf, S., additional, Khan, A., additional, Khan, S., additional, Kim, D. Y., additional, Kim, G. W., additional, Kim, H. B., additional, Kim, H. J., additional, Kim, H. L., additional, Kim, H. S., additional, Kim, M. B., additional, Kim, S. C., additional, Kim, S. K., additional, Kim, S. R., additional, Kim, W. T., additional, Kim, Y. D., additional, Kim, Y. H., additional, Kirdsiri, K., additional, Ko, Y. J., additional, Kobychev, V. V., additional, Kornoukhov, V., additional, Kuzminov, V. V., additional, Kwon, D. H., additional, Lee, C. H., additional, Lee, D. Y., additional, Lee, E. K., additional, Lee, H. J., additional, Lee, H. S., additional, Lee, J., additional, Lee, J. Y., additional, Lee, K. B., additional, Lee, M. H., additional, Lee, M. K., additional, Lee, S. W., additional, Lee, Y. C., additional, Leonard, D. S., additional, Lim, H. S., additional, Mailyan, B., additional, Makarov, E. P., additional, Nyanda, P., additional, Oh, Y., additional, Olsen, S. L., additional, Panasenko, S. I., additional, Park, H. K., additional, Park, H. S., additional, Park, K. S., additional, Park, S. Y., additional, Polischuk, O. G., additional, Prihtiadi, H., additional, Ra, S., additional, Ratkevich, S. S., additional, Rooh, G., additional, Sari, M. B., additional, Seo, J., additional, Seo, K. M., additional, Sharma, B., additional, Shin, K. A., additional, Shlegel, V. N., additional, Siyeon, K., additional, So, J., additional, Sokur, N. V., additional, Son, J. K., additional, Song, J. W., additional, Srisittipokakun, N., additional, Tretyak, V. I., additional, Wirawan, R., additional, Woo, K. R., additional, Yeon, H. J., additional, Yoon, Y. S., additional, and Yue, Q., additional

Published
2024
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9. Detection of Intermediate-Energy Solar Neutrinos by Means of Neutrino Capture by \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$${}^{115}$$\end{document}In Nuclei

Author

Barabanov, I. R., Bezrukov, L. B., Gurentsov, V. I., Novikova, G. Ya., Sinev, V. V., and Yanovich, E. A.

Published
2022
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10. Technical Design Report for the AMoRE $0\nu\beta\beta$ Decay Search Experiment

Author

Alenkov, V., Aryal, P., Beyer, J., Boiko, R. S., Boonin, K., Buzanov, O., Chanthima, N., Chernyak, M. K. Cheoun D. M., Choi, J., Choi, S., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gavriljuk, Yu. M., Gezhaev, A. M., Gurentsov, V. I., Ha, D. H, Hahn, I. S., Jang, J. H., Jeon, E. J., Jo, H. S., Joo, H., Kaewkhao, J., Kang, C. S., Kang, S. J., Kang, W. G, Karki, S., Kazalov, V. V., Khanbekov, N., Kim, G. B., Kim, H. J., Kim, H. L., Kim, H. O., Kim, I., Kim, J. H., Kim, K., Kim, S. K., Kim, S. R., Kim, Y. D., Kim, Y. H., Kirdsiri, K., Kobychev, V. V., Kornoukhov, V., Kuzminov, V. V., Lee, H. J., Lee, H. S., Lee, J. H., Lee, J. M., Lee, J. Y., Lee, K. B., Lee, M. H., Lee, M. K., Leonard, D. S., Li, J., Li, Y. J., Limkitjaroenporn, P., Ma, K. J., Mineev, O. V., Mokina, V. M., Olsen, S. L., Panasenko, S. I., Pandey, I., Park, H. K., Park, H. S., Park, K. S., Poda, D. V., Polischuk, O. G., Polozov, P., Prihtiadi, H., Ra, S. J., Ratkevich, S. S., Rooh, G., Siyeon, K., Srisittipokakun, N., So, J. H., Son, J. K., Tekueva, J. A., Tretyak, V. I., Veresnikova, A. V., Wirawan, R., Yakimenko, S. P., Yershov, N. V., Yoon, W. S., Yoon, Y. S., and Yue, Q.

Subjects
Physics - Instrumentation and Detectors, High Energy Physics - Experiment
Abstract

The AMoRE (Advanced Mo-based Rare process Experiment) project is a series of experiments that use advanced cryogenic techniques to search for the neutrinoless double-beta decay of \mohundred. The work is being carried out by an international collaboration of researchers from eight countries. These searches involve high precision measurements of radiation-induced temperature changes and scintillation light produced in ultra-pure \Mo[100]-enriched and \Ca[48]-depleted calcium molybdate ($\mathrm{^{48depl}Ca^{100}MoO_4}$) crystals that are located in a deep underground laboratory in Korea. The \mohundred nuclide was chosen for this \zeronubb decay search because of its high $Q$-value and favorable nuclear matrix element. Tests have demonstrated that \camo crystals produce the brightest scintillation light among all of the molybdate crystals, both at room and at cryogenic temperatures. $\mathrm{^{48depl}Ca^{100}MoO_4}$ crystals are being operated at milli-Kelvin temperatures and read out via specially developed metallic-magnetic-calorimeter (MMC) temperature sensors that have excellent energy resolution and relatively fast response times. The excellent energy resolution provides good discrimination of signal from backgrounds, and the fast response time is important for minimizing the irreducible background caused by random coincidence of two-neutrino double-beta decay events of \mohundred nuclei. Comparisons of the scintillating-light and phonon yields and pulse shape discrimination of the phonon signals will be used to provide redundant rejection of alpha-ray-induced backgrounds. An effective Majorana neutrino mass sensitivity that reaches the expected range of the inverted neutrino mass hierarchy, i.e., 20-50 meV, could be achieved with a 200~kg array of $\mathrm{^{48depl}Ca^{100}MoO_4}$ crystals operating for three years., Comment: 93 pages

Published
2015

12. Testing for New Physics with Low-Energy Anti-Neutrino Sources: LAMA as a Case Study

Author

Barabanov, I., Belli, P., Bernabei, R., Gurentsov, V. I., Kornoukhov, V. N., Miranda, O. G., Semikoz, V. B., and Valle, J. W. F.

Subjects
High Energy Physics - Phenomenology
Abstract

Some electroweak models with extended neutral currents, such as those based on the $E_6$ group, lead to an increase of the $\bar{\nu}-e$ scattering cross section at energies below 100 keV. We propose to search for the heavy Z' boson contribution in an experiment with a high-activity artificial neutrino source and with a large-mass detector. We present the case for the LAMA experiment with a large NaI(Tl) detector located at the Gran Sasso underground laboratory. The neutrino flux is known to within a one percent accuracy, in contrast to the reactor case and one can reach lower neutrino energies. Both features make our proposed experiment more sensitive to extended gauge models, such as the $\chi$ model. For a low enough background the sensitivity to the $Z_\chi$ boson mass would reach 600 GeV for one year running of the experiment., Comment: 22 pages, 7 figures included. Minor changes. Published in Nuc. Phys. B

Published
1998
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14. New Possibilities for -Cycle Solar Neutrino Registration by Use of Indium Detector.

Author

Barabanov, I. R., Bezrukov, L. B., Gurentsov, V. I., Novikova, G. Ya., Sinev, V. V., and Yanovich, E. A.

Subjects
SOLAR neutrinos, LIQUID scintillators, INDIUM, DETECTORS, SOLAR spectra, NEUTRINOS
Abstract

Low background segmented liquid scintillator detector, doped with an indium as a target for solar neutrino registration, can be used for measuring total solar neutrino spectrum including neutrinos. A detector consisting of small modules filled with liquid scintillator in the volume of 1–2 L is considered. Silicon matrices are used for light collection. The background of indium beta-activity is suppressed by triple coincidences. The detector of such a type can measure Be neutrino flux with high accuracy and independently check the measurement performed by the Borexino Collaboration. [ABSTRACT FROM AUTHOR]

Published
2023
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15. Energy Resolution of a Neodymium-Containing Scintillation Detector for Searching Neutrinoless Double Beta Decay of 150Nd.

Author

Barabanov, I. R., Veresnikova, A. V., Gavrylyuk, Yu. M., Gurentsov, V. I., Gangapshev, A. M., Kazalov, V. V., Novikova, G. Ya., Kalajokov, Z. Kh., Tekueva, D. A., Thazaplichev, M. Sh., and Yanovich, E. A.

Abstract

The energy resolution is calculated for a neodymium-containing liquid organic scintillation detector (Nd-OS) with a volume of several liters to search for neutrinoless double beta decay of 150Nd as a function of the neodymium concentration up to 5 g/L. The results are presented in detailed tables and graphs. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Measurement of the 14C Content in Liquid Scintillators by Means of a Small-Volume Detector in the Low-Background Chamber of the Baksan Neutrino Observatory

Author

Barabanov, I. R., Bezrukov, L. B., Veresnikova, A. V., Gavrilyuk, Yu. M., Gangapshev, A. M., Grishina, V. Yu., Gurentsov, V. I., Zavarzina, V. P., Kazalov, V. V., Krokhaleva, S. D., Kuz’minov, V. V., Kurlovich, A. S., Lubsandorzhiev, B. K., Lubsandorzhiev, S. B., Mezhokh, A. K., Morgalyuk, V. P., Naumov, P. Yu., Novikova, G. Ya., Petkov, V. B., Pshukov, A. M., Sidorenkov, A. Yu., Sinev, V. V., Umerov, Sh. I., Yanovich, E. A., Enquist, T., Kuusiniemi, P., Joutsenvaara, J., and Virkajarvi, A.

Published
2017
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17. Large-volume detector at the Baksan Neutrino Observatory for studies of natural neutrino fluxes for purposes of geo- and astrophysics

Author

Barabanov, I. R., Bezrukov, L. B., Veresnikova, A. V., Gavrilyuk, Yu. M., Gangapshev, A. M., Grishina, V. Yu., Gurentsov, V. I., Zavarzina, V. P., Kazalov, V. V., Krokhaleva, S. D., Kuz’minov, V. V., Kurlovich, A. S., Lubsandorzhiev, B. K., Lubsandorzhiev, S. B., Mezhokh, A. K., Morgalyuk, V. P., Naumov, P. Yu., Novikova, G. Ya., Petkov, V. B., Pshukov, A. M., Sidorenkov, A. Yu., Sinev, V. V., Umerov, Sh. I., Yanovich, E. A., Enquist, T., Kuusiniemi, P., Joutsenvaara, J., and Virkajarvi, A.

Published
2017
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23. Detection of Intermediate-Energy Solar Neutrinos by Means of Neutrino Capture by In Nuclei.

Author

Barabanov, I. R., Bezrukov, L. B., Gurentsov, V. I., Novikova, G. Ya., Sinev, V. V., and Yanovich, E. A.

Subjects
SOLAR neutrinos, NEUTRINOS, LIQUID scintillators, SOLAR spectra, SOLAR energy, TECHNOLOGICAL innovations
Abstract

A modification of the LENS (Low Energy Neutrino Spectroscopy) project for spectroscopy of solar neutrinos with energies above about 715 keV on the basis of new technologies and solutions is examined. The respective detector employs In nuclei as a target for neutrinos. The creation of a detector containing about 200 t of a scintillator loaded with 10 t of indium will make it possible to measure, within five years, the energy spectra of solar neutrinos from Be, neutrinos from the CNO cycle, and neutrinos with small systematic errors. The detector was simulated in the form of a set of cells of a liquid scintillator doped with indium (about 10 in weight). Necessary technical conditions for detector cells are formulated, and the possible counting rate for events induced by internal and external backgrounds and characterized by an energy release of 600 to 1600 keV is estimated. It is shown that such a detector is implementable, in principle. [ABSTRACT FROM AUTHOR]

Published
2022
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24. Study of single muons with the Large Volume Detector at the Gran Sasso Laboratory

Author

Aglietta, M., Alyea, E. D., Antonioli, P., Badino, G., Bari, G., Basile, M., Berezinsky, V. S., Bersani, F., Bertaina, M., Bertoni, R., Bruni, G., Cara Romeo, G., Castagnoli, C., Castellina, A., Chiavassa, A., Chinellato, J. A., Cifarelli, L., Cindolo, F., Contin, A., Dadykin, V. L., Dos Santos, L. G., Enikeev, R. I., Fulgione, W., Galeotti, P., Ghia, P., Giusti, P., Gomez, F., Granella, R., Grianti, F., Gurentsov, V. I., Iacobucci, G., Inoue, N., Kemp, E., Khalchukov, F. F., Korolkova, E. V., Korchaguin, P. V., Korchaguin, V. B., Kudryavtsev, V. A., Luvisetto, M., Malguin, A. S., Massam, T., Mengotti Silva, N., Morello, C., Nania, R., Navarra, G., Periale, L., Pesci, A., Picchi, P., Pless, I. A., Ryazhskaya, O. G., Saavedra, O., Saitoh, K., Sartorelli, G., Selvi, M., Taborgna, N., Talochkin, V. P., Trinchero, G. C., Tsuji, S., Turtelli, A., Vallania, P., Vernetto, S., Vigorito, C., Votano, L., Wada, T., Weinstein, R., Widgoff, M., Yakushev, V. F., Yamamoto, I., Zatsepin, G. T., and Zichich, A.

Published
2003
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25. First results from the AMoRE-Pilot neutrinoless double beta decay experiment

Author

Alenkov, V., primary, Bae, H. W., additional, Beyer, J., additional, Boiko, R. S., additional, Boonin, K., additional, Buzanov, O., additional, Chanthima, N., additional, Cheoun, M. K., additional, Chernyak, D. M., additional, Choe, J. S., additional, Choi, S., additional, Danevich, F. A., additional, Djamal, M., additional, Drung, D., additional, Enss, C., additional, Fleischmann, A., additional, Gangapshev, A. M., additional, Gastaldo, L., additional, Gavriljuk, Yu. M., additional, Gezhaev, A. M., additional, Grigoryeva, V. D., additional, Gurentsov, V. I., additional, Gylova, O., additional, Ha, C., additional, Ha, D. H., additional, Ha, E. J., additional, Hahn, I. S., additional, Jang, C. H., additional, Jeon, E. J., additional, Jeon, J. A., additional, Jo, H. S., additional, Kaewkhao, J., additional, Kang, C. S., additional, Kang, S. J., additional, Kang, W. G., additional, Kazalov, V. V., additional, Kempf, S., additional, Khan, A., additional, Khan, S., additional, Kim, D. Y., additional, Kim, G. W., additional, Kim, H. B., additional, Kim, H. J., additional, Kim, H. L., additional, Kim, H. S., additional, Kim, I., additional, Kim, S. C., additional, Kim, S. G., additional, Kim, S. K., additional, Kim, S. R., additional, Kim, W. T., additional, Kim, Y. D., additional, Kim, Y. H., additional, Kirdsiri, K., additional, Ko, Y. J., additional, Kobychev, V. V., additional, Kornoukhov, V., additional, Kuzminov, V. V., additional, Kwon, D. H., additional, Lee, C., additional, Lee, E. K., additional, Lee, H. J., additional, Lee, H. S., additional, Lee, J. S., additional, Lee, J. Y., additional, Lee, K. B., additional, Lee, M. H., additional, Lee, M. K., additional, Lee, S. W., additional, Lee, S. H., additional, Leonard, D., additional, Li, J., additional, Li, Y., additional, Limkitjaroenporn, P., additional, Makarov, E. P., additional, Oh, S. Y., additional, Oh, Y. M., additional, Olsen, S. L., additional, Pabitra, A., additional, Panasenko, S. I., additional, Pandey, I., additional, Park, C. W., additional, Park, H. K., additional, Park, H. S., additional, Park, K. S., additional, Park, S. Y., additional, Poda, D. V., additional, Polischuk, O. G., additional, Prihtiadi, H., additional, Ra, S. J., additional, Ratkevich, S. S., additional, Rooh, G., additional, Sari, M. B., additional, Seo, K. M., additional, Shin, J. W., additional, Shin, K. A., additional, Shlegel, V. N., additional, Siyeon, K., additional, So, J. H., additional, Son, J. K., additional, Srisittipokakun, N., additional, Sujita, K., additional, Tretyak, V. I., additional, Wirawan, R., additional, Woo, K. R., additional, Yoon, Y. S., additional, Yue, Q., additional, and Zaman, S. U., additional

Published
2019
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26. Towards ¹⁴C-free liquid scintillator

Author

Enqvist, T. (T), Barabanov, R. (R), Bezrukov, L. B. (L B), Gangapshev, A. M. (A M), Gavrilyuk, Y. M. (Y M), Grishina, V. Y. (V Yu), Gurentsov, V. I. (V I), Hissa, J. (J), Joutsenvaara, J. (J), Kazalov, V. V. (V V), Krokhaleva, S. (S), Kutuniva, J. (J), Kuusiniemi, P. (P), Kuzminov, V. V. (V V), Kurlovich, A. S. (A S), Loo, K. (K), Lubsandorzhiev, B. K. (B K), Lubsandorzhiev, S. (S), Morgalyuk, V. P. (V P), Novikova, G. Y. (G Y), Pshukov, A. M. (A M), Sinev, V. V. (V V), Słupecki, M. (M), Trzaska, W. H. (W H), Umerov, S. I. (Sh I), Veresnikova, A. V. (A V), Virkajärvi, A. (A), Yanovich, Y. A. (Y A), and Zavarzina, V. P. (V P)

Subjects
Physics::Instrumentation and Detectors
Abstract

A series of measurements has been started where the ¹⁴C concentration is determined from several liquid scintillator samples. A dedicated setup has been designed and constructed with the aim of measuring concentrations smaller than 10−18. Measurements take place in two underground laboratories: in the Baksan Neutrino Observatory, Russia, and in the new Callio Lab in the Pyhäsalmi mine, Finland. Low-energy neutrino detection with a liquid scintillator requires that the intrinsic ¹⁴C concentration in the liquid is extremely low. In the Borexino CTF detector the concentration of 2 × 10−18 has been achieved being the lowest value ever measured. In principle, the older the oil or gas source that the liquid scintillator is derived from and the deeper it situates, the smaller the ¹⁴C concentration is supposed to be. This, however, is not generally the case and the concentration is probably due to the U and Th content of the local environment.

Published
2017

27. Towards 14C-free liquid scintillator

Author

Enqvist, T., Barabanov, I. R., Bezrukov, L. B., Gangapshev, A. M., Gavrilyuk, Y. M., Grishina, V. Yu., Gurentsov, V. I., Hissa, J., Joutsenvaara, J., Kazalov, V. V., Krokhaleva, S., Kutuniva, J., Kuusiniemi, P., Kuzminov, V. V., Kurlovich, A. S., Loo, Kai, Lubsandorzhiev, B. K., Lubsandorzhiev, S., Morgalyuk, V. P., Novikova, G. Y., Pshukov, A. M., Sinev, V. V., Slupecki, Maciej, Trzaska, Wladyslaw, Umerov, Sh. I., Veresnikova, A. V., Virkaj arvi, A., Yanovich, Y. A., and Zavarzina, V. P.

Subjects
low-energy neutrino detection, Physics::Instrumentation and Detectors, ilmaisimet, hiili, neutriinot, liquid scintillators, isotope ratio
Abstract

A series of measurements has been started where the 14C concentration is determined from several liquid scintillator samples. A dedicated setup has been designed and constructed with the aim of measuring concentrations smaller than 10−18. Measurements take place in two underground laboratories: in the Baksan Neutrino Observatory, Russia, and in the new Callio Lab in the Pyhäsalmi mine, Finland. Low-energy neutrino detection with a liquid scintillator requires that the intrinsic 14C concentration in the liquid is extremely low. In the Borexino CTF detector the concentration of 2 × 10−18 has been achieved being the lowest value ever measured. In principle, the older the oil or gas source that the liquid scintillator is derived from and the deeper it situates, the smaller the 14C concentration is supposed to be. This, however, is not generally the case and the concentration is probably due to the U and Th content of the local environment. peerReviewed

Published
2017

28. Concentration of ¹⁴C in liquid scintillator

Author

Enqvist, T. (Timo), Barabanov, I. R. (I. R.), Bezrukov, L. B. (L. B.), Gangapshev, A. M. (A. M.), Gavrilyuk, Y. M. (Y. M.), Grishina, V. Y. (V. Yu.), Gurentsov, V. I. (V. I.), Hissa, J. (J.), Joutsenvaara, J. (Jari), Kazalov, V. V. (V. V.), Krokhaleva, S. (S.), Kutuniva, J. (Johanna), Kuusiniemi, P. (Pasi), Kuzminov, V. V. (V. V.), Kurlovich, A. S. (A. S.), Loo, K. (K.), Lubsandorzhiev, B. K. (B. K.), Lubsandorzhiev, S. (S.), Morgalyuk, V. P. (V. P.), Novikova, G. Y. (G. Y.), Pshukov, A. M. (A. M.), Sinev, V. V. (V. V.), Słupeckic, M. (M.), Trzaska, W. H. (W. H.), Umerov, S. I. (Sh. I.), Veresnikova, A. V. (A. V.), Virkajärvi, A. (A.), Yanovich, Y. A. (Y. A.), and Zavarzina, V. P. (V. P.)

Abstract

The main background hindering low-energy (≲ 200 keV) neutrino measurements with liquid scintillators comes from the minute remanence of the cosmogenic ¹⁴C (T₁/₂ ≃ 5700 a) present in the organic oil constituting the bulk of the scintillator. The β-decay endpoint energy of ¹⁴C is quite low, Q = 156 keV, and the counting rate from ¹⁴C is often reduced by threshold settings. However, too high concentration of ¹⁴C may results in pile-up pulses. For example, in the Borexino detector at Gran Sasso, Italy, being the most sensitive neutrino detector, the trigger rate is largely dominated by the ¹⁴C isotope [1] with the concentration of 2 × 10⁻¹⁸ [2] It is the lowest ¹⁴C concentration value ever measured. There are only a few results available on the ¹⁴C concentration. In addition to the one in Ref. [2] there are three other measurements reported in Refs. [3, 4, 5]. Obviously ¹⁴C cannot be removed from liquid scintillators by chemical methods, or by other methods in large quantities (liters). In principle, the older is the oil or gas source that the liquid scintillator is made of and the deeper it situates, the smaller the ¹⁴C concentration should be. This, however, is not generally the case and it is believed that the ratio depends on the activity (U and Th content) in the environment of the source. We are performing a series of measurements where the ¹⁴C concentration will be measured from several liquid scintillator samples. They need low-background environment and are taking place in two deep underground laboratories: in the new CallioLab laboratory in the Pyhäsalmi mine, Finland, and at the Baksan Neutrino Observatory, Russia, in order to reduce and better understand the systematical uncertainties. Preliminary results will be presented.

Published
2016

29. Measuring the 14C content in liquid scintillators

Author

Enqvist, T., Barabanov, I. R., Bezrukov, L. B., Gangapshev, A. M., Gavrilyuk, Y. M., Grishina, V. Yu., Gurentsov, V. I., Hissa, J., Joutsenvaara, J., Kazalov, V. V., Krokhaleva, S., Kutuniva, J., Kuusiniemi, P., Kuzminov, V. V., Kurlovich, A. S., Loo, Kai, Lubsandorzhiev, B. K., Lubsandorzhiev, S., Morgalyuk, V. P., Novikova, G. Y., Pshukov, A. M., Sinev, V. V., Slupecki, Maciej, Trzaska, Wladyslaw, Umerov, Sh. I., Veresnikova, A. V., Virkaj arvi, A., Yanovich, Y. A., Zavarzina, V. P., Fornengo, Nicolao, Regis, Marco, and Zechlin, Hannes-S.

Subjects
low-energy neutrino detection, hiili, liquid scintillators, isotope ratio
Abstract

We are going to perform a series of measurements where the 14C/12C ratio will be measured from several liquid scintillator samples with a dedicated setup. The setup is designed with the aim of measuring ratios smaller than 10−18. Measurements take place in two underground laboratories: in the Baksan Neutrino Observatory, Russia and in the Pyh¨asalmi mine, Finland. In Baksan the measurements started in 2015 and in Pyh¨asalmi they start in the beginning of 2015. In order to fully understand the operation of the setup and its background contributions a development of simulation packages has also been started. Low-energy neutrino detection with a liquid scintillator requires that the intrinsic 14C content in the liquid is extremely low. In the Borexino CTF detector at Gran Sasso, Italy the 14C/12C ratio of 2 × 10−18 has been achieved being the lowest 14C concentration ever measured. In principle, the older the oil or gas source that the liquid scintillator is derived of and the deeper it situates, the smaller the 14C/12C ratio is supposed to be. This, however, is not generally the case, and the ratio is probably determined by the U and Th content of the local environment. peerReviewed

Published
2016

30. Towards 14C-free liquid scintillator

Author

Enqvist, T, primary, Barabanov, I R, additional, Bezrukov, L B, additional, Gangapshev, A M, additional, Gavrilyuk, Y M, additional, Grishina, V Yu, additional, Gurentsov, V I, additional, Hissa, J, additional, Joutsenvaara, J, additional, Kazalov, V V, additional, Krokhaleva, S, additional, Kutuniva, J, additional, Kuusiniemi, P, additional, Kuzminov, V V, additional, Kurlovich, A S, additional, Loo, K, additional, Lubsandorzhiev, B K, additional, Lubsandorzhiev, S, additional, Morgalyuk, V P, additional, Novikova, G Y, additional, Pshukov, A M, additional, Sinev, V V, additional, lupecki, M S, additional, Trzaska, W H, additional, Umerov, Sh I, additional, Veresnikova, A V, additional, Virkajärvi, A, additional, Yanovich, Y A, additional, and Zavarzina, V P, additional

Published
2017
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31. Searches for Neutrinoless Double-Beta Decay of the Isotope 150Nd by Means of a Liquid Organic Scintillator Detector.

Author

Barabanov, I. R., Bezrukov, L. B., Veresnikova, A. V., Gavriluk, Yu. M., Gurentsov, V. I., Kazalov, V. V., Kuzminov, V. V., Novikova, G. Ya., Semenov, S. V., Sinev, V. V., Tsvetkov, G. O., and Yanovich, E. A.

Subjects
LIQUID scintillators, ISOTOPES, NEODYMIUM isotopes, DETECTORS
Abstract

Because of a high energy of the neutrinoless double-beta decay (0ν2β) of the isotope 150Nd and a high value of the daughter-nucleus charge Zf, 150Nd is one of the most promising isotopes for 0ν2β-decay searches. A 150Nd-containing detector on the basis of a liquid organic scintillator permits employing large isotope masses. Requirements on the radiation purity of the neodymium sample used are determined. The possible design of a large-scale detector of this type and expected results are considered. [ABSTRACT FROM AUTHOR]

Published
2019
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32. Measuring the14C content in liquid scintillators

Author

Enqvist, T, primary, Barabanov, I R, additional, Bezrukov, L B, additional, Gangapshev, A M, additional, Gavrilyuk, Y M, additional, Yu Grishina, V, additional, Gurentsov, V I, additional, Hissa, J, additional, Joutsenvaara, J, additional, Kazalov, V V, additional, Krokhaleva, S, additional, Kutuniva, J, additional, Kuusiniemi, P, additional, Kuzminov, V V, additional, Kurlovich, A S, additional, Loo, K, additional, Lubsandorzhiev, B K, additional, Lubsandorzhiev, S, additional, Morgalyuk, V P, additional, Novikova, G Y, additional, Pshukov, A M, additional, Sinev, V V, additional, Słupecki, M, additional, Trzaska, W H, additional, Umerov, Sh I, additional, Veresnikova, A V, additional, Virkajärvi, A, additional, Yanovich, Y A, additional, and Zavarzina, V P, additional

Published
2016
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34. Measurement of the 14C Content in Liquid Scintillators by Means of a Small-Volume Detector in the Low-Background Chamber of the Baksan Neutrino Observatory.

Author

Barabanov, I. R., Bezrukov, L. B., Veresnikova, A. V., Gavrilyuk, Yu. M., Gangapshev, A. M., Grishina, V. Yu., Gurentsov, V. I., Zavarzina, V. P., Kazalov, V. V., Krokhaleva, S. D., Kuz'minov, V. V., Kurlovich, A. S., Lubsandorzhiev, B. K., Lubsandorzhiev, S. B., Mezhokh, A. K., Morgalyuk, V. P., Naumov, P. Yu., Novikova, G. Ya., Petkov, V. B., and Pshukov, A. M.

Subjects
ISOTOPIC analysis, RADIOACTIVITY
Abstract

A setup for measuring natural-radioactivity backgrounds and ultralow concentrations of the isotope 14C in samples of a liquid organic scintillator was created at the low-background laboratory of the Baksan Neutrino Observatory (Institute for Nuclear Research, Russian Academy of Sciences) at a depth of 4900 mwe. The concentration of the radiocarbon 14C in a sample of a scintillator based on domestically produced linear alkylbenzene was measured, and it was found that 14C/12C (3.3 ± 0.5) × 10-17. [ABSTRACT FROM AUTHOR]

Published
2017
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36. MONOLITH experiment proposal: a massive magnetized iron detector for neutrino oscillation studies

Author

Agafonova, N Y, Ambrosio, M, Amelchakov, M, Antonioli, P, Aprile, E, Aynutdinov, V, Ballhaussen, C, Bari, G, Benaceur, R, Bencivenni, G, Bergamasco, L, Bologna, G, Bonesini, M, Bruni, G, Bruski, N, Büsser, F W, Chernov, D, Cicchetti, N, Cremonesi, O, Curioni, A, Frekers, D, Galeotti, P, Garfagnini, A, Geiser, A, Gharbi, F, Giugni, D, Giusti, P, Gurentsov, V I, Gustavino, C, Gutsche, O, Heinzelmann, G, Höpfner, K, Kellmann, T, Kindin, V, Klanner, R, Koppitz, B, Kokoulin, R, Kompaniets, K, Konovalov, A, Kovzelev, A, Kueckmann, J, Malgin, A S, Mannocchi, G, Margotti, A, Maschuw, R, Menghetti, H, Monacelli, P, Morra, O, Murtas, F, Murtas, G P, Nania, R, Naroska, B, Negri, P, Paganoni, M, Pesci, A, Periale, L, Peskov, Vladimir, Petrukhin, A, Picchi, P, Pullia, A, Ryazhskaya, O G, Ragazzi, S, Redaelli, N, Ronga, F, Sartorelli, G, Satta, L, Schmidt-Parzefall, W, Selvi, M, Souga, C, Tabarelli de Fatis, Tommaso, Terranova, F, Trabelsi, A, Trinchero, G, Van Staa, R, Villone, B, Winter, Klaus, Yakushev, V F, Yanson, E, and Yashin I

Subjects
Detectors and Experimental Techniques
Published
2000

38. LENS-SOL: A DETECTOR FOR MEASURING THE NEUTRINO LUMINOSITY OF THE SUN

Author

BACK, H., primary, BARABANOV, I. R., additional, BENZIGER, J., additional, BEZRUKOV, L. B., additional, CHAMPAGNE, A., additional, CHANG, Z., additional, GAVRIN, V., additional, GARNOV, A., additional, GURENTSOV, V. I., additional, HAHN, R. L., additional, KAMISHKOV, Y., additional, KORNOUKHOV, V. N., additional, MUSIKAS, C., additional, PITT, M., additional, RAGHAVAN, R. S., additional, VOGELAAR, R. B., additional, YANOVITCH, E. A., additional, and YEH, M., additional

Published
2005
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39. Measurement of the cross sections for the production of the isotopes 74As, 68Ge, 65Zn, and 60Co from natural and enriched germanium irradiated with 100-MeV protons.

Author

Barabanov, I. R., Bezrukov, L. B., Gurentsov, V. I., Zhuykov, B. L., Kianovsky, S. V., Kornoukhov, V. N., Kohanuk, V. M., and Yanovich, E. A.

Subjects
ISOTOPES, RADIOACTIVE decay, NUCLEAR research, COLLISIONS (Nuclear physics), NUCLIDES
Abstract

The cross sections for the production of the radioactive isotopes 74As, 68Ge, 65Zn, and 60Co in metallic germanium irradiated with 100-MeV protons were measured, the experiments being performed both with germanium of natural isotopic composition and germanium enriched in the isotope 76Ge. The targets were irradiated with a proton beam at the facility for the production of radionuclides at the accelerator of the Institute for Nuclear Research (INR, Moscow). The data obtained will further be used to calculate the background of radioactive isotopes formed by nuclear cascades of cosmic-ray muons in new-generation experiments devoted to searches for the neutrinoless double-beta decay of 76Ge at underground laboratories. [ABSTRACT FROM AUTHOR]

Published
2010
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40. MONOLITH: A massive magnetized iron detector for neutrino oscillation studies

Author

Agafonova, N. Y., Ambrosio, M., Amelchakov, M., Antonioli, P., Aprile, E., Aynutdinov, V., Ballhausen, C., Bari, G., Benaceur, R., Bencivenni, G., Bergamasco, L., Bologna, G., Bonesini, M., Bruni, G., Bruski, N., Busser, F. W., Chernov, D., Cicchetti, N., Cremonesi, O., Curioni, A., Frekers, D., Galeotti, P., Garfagnini, A., Geiser, A., Gharbi, F., Giugni, D., Giusti, P., Gurentsov, V. I., Gustavino, C., Oliver Gutsche, Heinzelmann, G., Hoepfner, K., Kellmann, T., Kindin, V., Klanner, R., Koppitz, B., Kokoulin, R., Kompaniets, K., Konovalov, A., Kovzelev, A., Kuckmann, J., Malgin, A. S., Mannocchi, G., Margotti, A., Maschuw, R., Menghetti, H., Monacelli, Piero, Morra, O., Murtas, F., Murtas, G. P., Nania, R., Naroska, B., Negri, P., Paganoni, M., Pesci, A., Periale, L., Peskov, V., Petrukhin, A., Picchi, P., Pullia, A., Ryazhskaya, O. G., Ragazzi, S., Redaelli, Nicola Giuseppe, Ronga, F., Sartorelli, G., Satta, L., Schmidt-Parzefall, W., Selvi, M., Souga, C., Tabarelli Fatis, T., Terranova, F., Trabelsi, A., Trinchero, G., Staa, R., Villone, B., Winter, K., Yakushev, V. F., Yanson, E., and Yashin, I.

42. Searching for a neutrino magnetic moment with an artificial source and NaI(Tl) scintillators deep underground

Author

Barabanov, I. R., Pierluigi Belli, Bernabei, R., Besida, O., Cherkhovsky, V. I., Dai, C. J., Ding, L. K., Di Nicolantonio, W., Gerbier, G., Giraud-Heraud, Y., Gurentsov, V. I., Ianovich, E. A., Incicchitti, A., Janz, V. E., Kornoukhov, V. N., Kuang, H. H., Landoni, V., Ma, J. M., Mallet, J., Montecchia, F., Mosca, L., Orekhov, I. V., Panshin, C. V., Prosperi, D., and Tao, C.

Subjects
Detectors and Experimental Techniques

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