Your search keyword '"Khanbekov, N."' showing total 20 results

1. 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

2. Application of the Monte-Carlo refractive index matching (MCRIM) technique to the determination of the absolute light yield of a calcium molybdate scintillator

Author

Alenkov, V., Buzanov, O. A., Khanbekov, N., Kornoukhov, V. N., Kraus, H., Mikhailik, V. B., and Shuvaeva, V. A.

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment

Abstract

The use of 40Ca100MoO in experimental searches for neutrinoless double beta decay (0{\nu}DBD) relies on knowledge of fundamental scintillation properties of the material. In this work we determine the absolute light yield of calcium molybdate using Monte-Carlo refractive index matching technique (MCRIM). The MCRIM technique is a combination of experiment and simulations that allows the absolute light yield of scintillators to be determined by taking into account effects of refraction, scattering and absorption in the material. The light collection efficiency of the scintillator-detector assembly was simulated using the ZEMAX ray-tracing software. By tuning the optical parameters of the scintillation crystal, a model was derived that gives good agreement with the experimental results. It is shown that the light collection efficiency of scintillators increases with transmittance and scattering due to an enhanced probability for photons to escape the crystal volume. Using MCRIM, the absolute light yield for the 40Ca100MoO4 scintillator was found to be 7.5+-1.2 ph/keV at room temperature. Comparative measurements using a CaWO4 scintillator as a reference show good agreement with this result. In that way, the study demonstrated the potential of the MCRIM technique as a tool for quantitative characterization of scintillation materials.

Published

2013

3. The development of a cryogenic detector with CaMoO 4 crystals for neutrinoless double beta decay search

Author

Lee, S.J., Choi, J.H., Danevich, F.A., Jang, Y.S., Kang, W.G., Khanbekov, N., Kim, H.J., Kim, I.H., Kim, S.C., Kim, S.K., Kim, Y.D., Kim, Y.H., Kobychev, V.V., Kornoukhov, V.N., Lee, J.I., Lee, J.S., Lee, K.B., Lee, M.K., Lee, Y.H., Myung, S.S., So, J.H., Tretyak, V.I., and Yuryev, Y.

Published

2011

4. Ultrapurification of isotopically enriched materials for 40Ca100MoO4 crystal growth

Author

Alenkov, V. V., Buzanov, O. A., Dosovitskii, A. E., Kornoukhov, V. N., Mikhlin, A. L., Moseev, P. S., and Khanbekov, N. D.

Published

2013

5. A Study of Radioactive Contamination of Crystals for the AMoRE Experiment

Author

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

Published

2016

6. AMoRE: Collaboration for searches for the neutrinoless double-beta decay of the isotope of 100Mo with the aid of 40Ca100MoO4 as a cryogenic scintillation detector

Author

Khanbekov, N. D., primary

Published

2013

7. Application of the Monte-Carlo refractive index matching (MCRIM) technique to the determination of the absolute light yield of a calcium molybdate scintillator

Author

Alenkov, V, primary, Buzanov, O A, additional, Khanbekov, N, additional, Kornoukhov, V N, additional, Kraus, H, additional, Mikhailik, V B, additional, and Shuvaeva, V A, additional

Published

2013

8. A study of CaMoO4 crystals for the AMoRE Experiment

Author

So, J. H., primary, Kim, H. J., additional, Alenkov, V. V., additional, Annenkov, A. N., additional, Bhang, H., additional, Boiko, R. S., additional, Buzanov, O. A., additional, Chernyak, D. M., additional, Choi, J. H., additional, Choi, S., additional, Danevich, F. A., additional, Efendiev, K. V., additional, Enssg, C., additional, Fleischmann, A., additional, Gangapshev, A. M., additional, Gastaldo, L., additional, Gavryluk, Yu. M., additional, Gezhaev, A. M., additional, Hwang, Y. S., additional, Jang, Y. S., additional, Jiang, H., additional, Kang, W. G., additional, Kazalov, V. V., additional, Khanbekov, N. D., additional, Kim, G. B., additional, Kim, S. K., additional, Kim, S. C., additional, Kim, Y. D., additional, Kim, Y. H., additional, Kobychev, V. V., additional, Kornoukhov, V. N., additional, Kuzminov, V. V., additional, Lee, H. J., additional, Lee, H. S., additional, Lee, K. B., additional, Lee, M. J., additional, Lee, M. K., additional, Lee, S. J., additional, Li, J., additional, Mokina, V. M., additional, Myung, S. S., additional, Nikolaiko, A. S., additional, Olsen, S. L., additional, Panasenko, S. I., additional, Poda, D. V., additional, Podviyanuk, R. B., additional, Polischuk, O. G., additional, Polozov, P. A., additional, Ratkevich, S. S., additional, Satou, Y., additional, Tanida, K., additional, Tretyak, V. I., additional, Yakimenko, S. P., additional, Yoon, W. S., additional, Yue, Q., additional, and Yuryev, Y. N., additional

Published

2012

9. Scintillation Properties and Internal Background Study of $^{40}$Ca$^{100}$MoO$_{4}$ Crystal Scintillators for Neutrino-Less Double Beta Decay Search

Author

So, J. H., primary, Kim, H. J., additional, Alenkov, V. V., additional, Annenkov, A. N., additional, Bhang, H., additional, Boiko, R. S., additional, Buzanov, O. A., additional, Chernyak, D. M., additional, Choi, J. H., additional, Choi, S., additional, Danevich, F. A., additional, Efendiev, K. V., additional, Gangapshev, A. M., additional, Gavryluk, Y. M., additional, Gezhaev, A. M., additional, Hwang, Y. S., additional, Jiang, H., additional, Kang, W. G., additional, Kazalov, V. V., additional, Khanbekov, N. D., additional, Kim, G. B., additional, Kim, S. K., additional, Kim, S. C., additional, Kim, Y. D., additional, Kim, Y. H., additional, Kobychev, V. V., additional, Kornoukhov, V. N., additional, Kuzminov, V. V., additional, Lee, H. S., additional, Lee, J. I., additional, Lee, J. M., additional, Lee, K. B., additional, Lee, M. J., additional, Lee, M. K., additional, Lee, S. J., additional, Li, J., additional, Li, X., additional, Mokina, V. M., additional, Myung, S. S., additional, Nikolaiko, A. S., additional, Olsen, S., additional, Park, H., additional, Panasenko, S. I., additional, Poda, D. V., additional, Podviyanuk, R. B., additional, Polischuk, O. G., additional, Ratkevich, S. S., additional, Satou, Y., additional, Tanida, K., additional, Tretyak, V. I., additional, Yakimenko, S. P., additional, and Yue, Q., additional

Published

2012

10. AMoRE experiment: a search for neutrinoless double beta decay of100Mo isotope with40Ca100MoO4cryogenic scintillation detector

Author

Bhang, H, primary, Boiko, R S, additional, Chernyak, D M, additional, Choi, J H, additional, Choi, S, additional, Danevich, F A, additional, Efendiev, K V, additional, Enss, C, additional, Fleischmann, A, additional, Gangapshev, A M, additional, Gastaldo, L, additional, Gezhaev, A M, additional, Hwang, Y S, additional, Jiang, H, additional, Kang, W G, additional, Kazalov, V V, additional, Khanbekov, N D, additional, Kim, H J, additional, Kim, K B, additional, Kim, S K, additional, Kim, S C, additional, Kim, Y D, additional, Kim, Y H, additional, Kobychev, V V, additional, Kornoukhov, V N, additional, Kuzminov, V V, additional, Mokina, V M, additional, Lee, H S, additional, Lee, J I, additional, Lee, J M, additional, Lee, K B, additional, Lee, M J, additional, Lee, M K, additional, Lee, S J, additional, Li, J, additional, Li, X, additional, Myung, S S, additional, Nikolaiko, A S, additional, Olsen, S, additional, Panasenko, S I, additional, Park, H, additional, Poda, D V, additional, Podviyanuk, R B, additional, Polischuk, O G, additional, Polozov, P A, additional, Ratkevich, S S, additional, Satou, Y, additional, So, J H, additional, Tanida, K, additional, Tretyak, V I, additional, Yakimenko, S P, additional, Yue, Q, additional, and Yuryev, Y, additional

Published

2012

11. Growth and characterization of isotopically enriched 40Ca100MoO4 single crystals for rare event search experiments

Author

Alenkov, V. V., primary, Buzanov, O. A., additional, Khanbekov, N., additional, Kim, S. K., additional, Kim, H. J., additional, Kornoukhov, V. N., additional, Kraus, H., additional, and Mikhailik, V. B., additional

Published

2011

12. The development of a cryogenic detector with CaMoO4 crystals for neutrinoless double beta decay search

Author

Lee, S.J., primary, Choi, J.H., additional, Danevich, F.A., additional, Jang, Y.S., additional, Kang, W.G., additional, Khanbekov, N., additional, Kim, H.J., additional, Kim, I.H., additional, Kim, S.C., additional, Kim, S.K., additional, Kim, Y.D., additional, Kim, Y.H., additional, Kobychev, V.V., additional, Kornoukhov, V.N., additional, Lee, J.I., additional, Lee, J.S., additional, Lee, K.B., additional, Lee, M.K., additional, Lee, Y.H., additional, Myung, S.S., additional, So, J.H., additional, Tretyak, V.I., additional, and Yuryev, Y., additional

Published

2011

13. Ultrapurification of isotopically enriched materials for CaMoO crystal growth.

Author

Alenkov, V., Buzanov, O., Dosovitskii, A., Kornoukhov, V., Mikhlin, A., Moseev, P., and Khanbekov, N.

Subjects

CALCIUM compounds, CRYSTAL growth, CHEMICAL purification, SINGLE crystals, RADIOISOTOPES, METAL inclusions, SCINTILLATORS, MOLYBDATES

Abstract

This paper describes ultrapurification of isotopically enriched calcium and molybdenum compounds and CaMoO calcium molybdate growth charge in order to remove radioactive uranium, thorium, and radium impurities. CaMoO single crystals grown from such charges are needed for the fabrication of scintillator elements of the cryogenic detector for the AMoRE project: a search for Mo neutrino-less double-beta decay. [ABSTRACT FROM AUTHOR]

Published

2013

14. AMoRE: Collaboration for searches for the neutrinoless double-beta decay of the isotope of 100Mo with the aid of 40Ca100MoO4 as a cryogenic scintillation detector.

Author

Khanbekov, N. D.

Subjects

*NEUTRINOLESS double beta decay, *SCINTILLATION counters, *SINGLE crystals, *CALCIUM compounds, *MOLYBDENUM isotopes, *NEUTRINO mass

Abstract

The AMoRE (Advanced Mo based Rare process Experiment) Collaboration is planning to employ 40Ca 100MoO 4 single crystals as a cryogenic Scintillation detector for studying the neutrinoless double-beta decay of the isotope 100Mo. A simultaneous readout of phonon and scintillation signals is performed in order to suppress the intrinsic background. The planned sensitivity of the experiment that would employ 100 kg of 40Ca 100MoO 4 over five years of data accumulation would be T1/20ν = 3 × 10 26 yr, which corresponds to values of the effective Majorana neutrino mass in the range of 〈 mν〉 ∼ 0.02–0.06 eV. [ABSTRACT FROM AUTHOR]

Published

2013

15. DATA ANALYSIS OF THE INTERNAL BACKGROUND MEASUREMENTS OF 40Ca100MoO4 SCINTILLATION CRYSTALS.

Author

Khanbekov, N. D., Alenkov, V. V., Burenkov, A. A., Buzanov, O. A., and Kornoukhov, V. N.

Subjects

*DATA analysis, *CRYSTALLIZATION, *NEUTRINOS, *DOUBLE beta decay, *ISOTOPES

Abstract

The sensitivity of neutrinoless double beta (0v2β) decay experiments is mainly dependent on the internal background of a detector which, in its turn, is defined by the purity of material and possibility for selection of background events. The AMoRE (Advanced Mo based Rare process Experiment) collaboration plans to use 40Ca100MoO4 scintillation crystals as a detector for search of 0v2β decay of 100Mo isotope. A purpose of this paper is further investigation of internal background of Ca100MoO4 scintillation elements with a low background setup at YangYang underground laboratory. We present new approaches for selection of background events from analyzing data and the latest updated values of background index of 40Ca100MoO4 crystals as a result of the new technique application. [ABSTRACT FROM AUTHOR]

Published

2013

16. Scintillation Properties and Internal Background Study of ^40Ca^100MoO4 Crystal Scintillators for Neutrino-Less Double Beta Decay Search.

Author

So, J. H., Kim, H. J., Alenkov, V. V., Annenkov, A. N., Bhang, H., Boiko, R. S., Buzanov, O. A., Chernyak, D. M., Choi, J. H., Choi, S., Danevich, F. A., Efendiev, K. V., Gangapshev, A. M., Gavryluk, Yu. M., Gezhaev, A. M., Hwang, Y. S., Jiang, H., Kang, W. G., Kazalov, V. V., and Khanbekov, N. D.

Subjects

SCINTILLATION counters, RADIOACTIVE decay, CALCIUM compounds, CRYSTALLOGRAPHY, NEUTRON counters

Abstract

Scintillation properties and radioactive contamination of calcium molybdate scintillating crystals depleted in ^48Ca and enriched in ^100Mo (^40Ca^100MoO4) have been studied to prepare a ^100Mo-based neutrinoless double beta decay experiment. The prospects of a neutrinoless double beta decay experiment using ^40Ca^100 MoO4 crystals are discussed. [ABSTRACT FROM PUBLISHER]

Published

2012

17. Growth and characterization of isotopically enriched 40Ca100MoO4 single crystals for rare event search experiments.

Author

Alenkov, V. V., Buzanov, O. A., Khanbekov, N., Kim, S. K., Kim, H. J., Kornoukhov, V. N., Kraus, H., and Mikhailik, V. B.

Abstract

Calcium molybdate is considered as a very promising scintillator material for experimental studies of rare processes. This paper reports on the production and characterization of a 40Ca100MoO4 scintillator. Using the Czochralski technique, a crystal of high optical quality with total mass 0.55 kg, 42 mm diameter (minimum) and 53 mm 1ength of the cylindrical section was produced from isotopically enriched raw materials, containing 96.1% of 100Mo and 99.964% of 40Ca. To satisfy the requirement of low intrinsic radioactivity the purity of the materials was monitored at different stages of the production process and it is shown that the concentration of 238U and 232Th in the final crystal does not exceed 0.05 ppb. The scintillation properties of 40Ca100MoO4 were measured over the 8 - 300 K temperature range and it is found that the light yield of the 40Ca100MoO4 crystal is very similar to that of the CaMoO4 reference scintillator. (© 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim) [ABSTRACT FROM AUTHOR]

Published

2011

18. Data analysis of the internal background measurements of 40Ca100MoO4 scintillation crystals

Author

Khanbekov, N. D., Alenkov, V. V., Alexander Burenkov, Buzanov, O. A., and Kornoukhov, V. N.

Subjects

radioactive background, low-background physics, data analysis, time-amplitude analysis, calcium molybdate, scintillators, lcsh:Atomic physics. Constitution and properties of matter, neutrinoless double beta decay, lcsh:QC170-197

Abstract

The sensitivity of neutrinoless double beta (02) decay experiments is mainly dependent on the internal background of a detector which, in its turn, is defined by the purity of material and possibility for selection of background events. The AMoRE (Advanced Mo based Rare process Experiment) collaboration plans to use 40Ca100MoO4 scintillation crystals as a detector for search of 02 decay of 100Mo isotope. A purpose of this pa-per is further investigation of internal background of 40Ca100MoO4 scintillation elements with a low background setup at YangYang underground laboratory. We present new approaches for selection of background events from analyzing data and the latest updated values of background index of 40Ca100MoO4 crystals as a result of the new technique application.

19. AMoRE experiment: a search for neutrinoless double beta decay of 100Mo isotope with 40Ca100MoO4 cryogenic scintillation detector.

Author

Bhang, H., Boiko, R. S., Chernyak, D. M., Choi, J. H., Choi, S., Danevich, F. A., Efendiev, K. V., Enss, C., Fleischmann, A., Gangapshev, A. M., Gastaldo, L., Gezhaev, A. M., Hwang, Y. S., Jiang, H., Kang, W. G., Kazalov, V. V., Khanbekov, N. D., Kim, H. J., Kim, K. B., and Kim, S. K.

Published

2012

20. The development of a cryogenic detector with CaMoO4 crystals for neutrinoless double beta decay search

Author

Lee, S.J., Choi, J.H., Danevich, F.A., Jang, Y.S., Kang, W.G., Khanbekov, N., Kim, H.J., Kim, I.H., Kim, S.C., Kim, S.K., Kim, Y.D., Kim, Y.H., Kobychev, V.V., Kornoukhov, V.N., Lee, J.I., Lee, J.S., Lee, K.B., Lee, M.K., Lee, Y.H., and Myung, S.S.

Subjects

*CHEMICAL detectors, *LOW temperature engineering, *CALCIUM compounds, *NEUTRINOLESS double beta decay, *NEUTRINO mass, *SCINTILLATORS, *PHASE transitions, *FORCE & energy

Abstract

Abstract: The search for neutrinoless double beta decay (0νββ) is a key experiment for evaluating the mass of the neutrino and for determining the Majorana/Dirac nature of neutrinos. A scintillating CaMoO4 crystal is a good material for use in investigating 0νββ with cryogenic detectors. The high transition energy (Q =3034keV) and nearly 10% natural abundance of 100Mo, together with the scintillating property of the crystal, provide favorable conditions to search for 0νββ of 100Mo. We report a prototype experiment operating at low temperatures using a CaMoO4 crystal as a particle absorber. Prior to testing of isotopically-enriched 40Ca100MoO4 crystals, a CaMoO4 crystal with Mo of natural isotopic composition was tested. Using a metallic magnetic calorimeter as a temperature sensor, we achieved high energy resolutions for alpha particles and low-energy gamma rays. This experiment shows the feasibility of scaling up the crystal size to perform a high sensitivity search for 0νββ decay of 100Mo. [Copyright &y& Elsevier]

Published

2011