Alpha backgrounds in the AMoRE-Pilot experiment

V. Alenkov; H. W. Bae; J. Beyer; R. S. Boiko; K. Boonin; O. Buzanov; N. Chanthima; M. K. Cheoun; S. H. Choi; F. A. Danevich; M. Djamal; D. Drung; C. Enss; A. Fleischmann; A. Gangapshev; L. Gastaldo; Yu M. Gavriljuk; A. Gezhaev; V. D. Grigoryeva; V. Gurentsov; D. H. Ha; C. Ha; E. J. Ha; I. Hahn; E. J. Jeon; J. Jeon; H. S. Jo; J. Kaewkhao; C. S. Kang; S. J. Kang; W. G. Kang; S. Karki; V. Kazalov; A. Khan; S. Khan; D. Y. Kim; G. W. Kim; H. B. Kim; H. J. Kim; H. L. Kim; H. S. Kim; I. Kim; W. T. Kim; S. R. Kim; S. C. Kim; S. K. Kim; Y. D. Kim; Y. H. Kim; K. Kirdsiri; Y. J. Ko; V. V. Kobychev; V. Kornoukhov; V. Kuz’minov; D. H. Kwon; C. Lee; E. K. Lee; H. J. Lee; H. S. Lee; J. Lee; J. S. Lee; J. Y. Lee; K. B. Lee; M. H. Lee; M. K. Lee; S. H. Lee; S. W. Lee; S. W. Lee; D. S. Leonard; J. Li; Y. Li; P. Limkitjaroenporn; B. Mailyan; E. P. Makarov; S. Y. Oh; Y. M. Oh; O. Gileva; S. Olsen; A. Pabitra; S. Panasenko; I. Pandey; C. W. Park; H. K. Park; H. S. Park; K. S. Park; S. Y. Park; O. G. Polischuk; H. Prihtiadi; S. J. Ra; S. Ratkevich; G. Rooh; M. B. Sari; J. Seo; K. M. Seo; J. W. Shin; K. A. Shin; V. N. Shlegel; K. Siyeon; N. V. Sokur; J. K. Son; N. Srisittipokakun; N. Toibaev; V. I. Tretyak; R. Wirawan; K. R. Woo; Y. S. Yoon; Q. Yue

doi:10.1140/epjc/s10052-022-11104-3

Alpha backgrounds in the AMoRE-Pilot experiment

V. Alenkov, H. W. Bae, J. Beyer, R. S. Boiko, K. Boonin, O. Buzanov, N. Chanthima, M. K. Cheoun, S. H. Choi, F. A. Danevich, M. Djamal, D. Drung, C. Enss, A. Fleischmann, A. Gangapshev, L. Gastaldo, Yu M. Gavriljuk, A. Gezhaev, V. D. Grigoryeva, V. GurentsovD. H. Ha, C. Ha, E. J. Ha, I. Hahn, E. J. Jeon, J. Jeon, H. S. Jo, J. Kaewkhao, C. S. Kang, S. J. Kang, W. G. Kang, S. Karki, V. Kazalov, A. Khan, S. Khan, D. Y. Kim, G. W. Kim, H. B. Kim, H. J. Kim, H. L. Kim, H. S. Kim, I. Kim, W. T. Kim, S. R. Kim, S. C. Kim, S. K. Kim, Y. D. Kim, Y. H. Kim, K. Kirdsiri, Y. J. Ko, V. V. Kobychev, V. Kornoukhov, V. Kuz’minov, D. H. Kwon, C. Lee, E. K. Lee, H. J. Lee, H. S. Lee, J. Lee, J. S. Lee, J. Y. Lee, K. B. Lee, M. H. Lee, M. K. Lee, S. H. Lee, S. W. Lee, S. W. Lee, D. S. Leonard, J. Li, Y. Li, P. Limkitjaroenporn, B. Mailyan, E. P. Makarov, S. Y. Oh, Y. M. Oh, O. Gileva, S. Olsen, A. Pabitra, S. Panasenko, I. Pandey, C. W. Park, H. K. Park, H. S. Park, K. S. Park, S. Y. Park, O. G. Polischuk, H. Prihtiadi, S. J. Ra, S. Ratkevich, G. Rooh, M. B. Sari, J. Seo, K. M. Seo, J. W. Shin, K. A. Shin, V. N. Shlegel, K. Siyeon, N. V. Sokur, J. K. Son, N. Srisittipokakun, N. Toibaev, V. I. Tretyak, R. Wirawan, K. R. Woo, Y. S. Yoon, Q. Yue

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Abstract

The Advanced Mo-based Rare process Experiment (AMoRE)-Pilot experiment is an initial phase of the AMoRE search for neutrinoless double beta decay of ¹⁰⁰Mo, with the purpose of investigating the level and sources of backgrounds. Searches for neutrinoless double beta decay generally require ultimately low backgrounds. Surface α decays on the crystals themselves or nearby materials can deposit a continuum of energies that can be as high as the Q-value of the decay itself and may fall in the region of interest (ROI). To understand these background events, we studied backgrounds from radioactive contaminations internal to and on the surface of the crystals or nearby materials with Geant4-based Monte Carlo simulations. In this study, we report on the measured α energy spectra fitted with the corresponding simulated spectra for six crystal detectors, where sources of background contributions could be identified through high energy α peaks and continuum parts in the energy spectrum for both internal and surface contaminations. We determine the low-energy contributions from internal and surface α contaminations by extrapolating from the α background fitting model.

Original language	English
Article number	1140
Journal	European Physical Journal C
Volume	82
Issue number	12
DOIs	https://doi.org/10.1140/epjc/s10052-022-11104-3
State	Published - Dec 2022

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10.1140/epjc/s10052-022-11104-3

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Alenkov, V., Bae, H. W., Beyer, J., Boiko, R. S., Boonin, K., Buzanov, O., Chanthima, N., Cheoun, M. K., Choi, S. H., Danevich, F. A., Djamal, M., Drung, D., Enss, C., Fleischmann, A., Gangapshev, A., Gastaldo, L., Gavriljuk, Y. M., Gezhaev, A., Grigoryeva, V. D., ... Yue, Q. (2022). Alpha backgrounds in the AMoRE-Pilot experiment. European Physical Journal C, 82(12), Article 1140. https://doi.org/10.1140/epjc/s10052-022-11104-3

@article{24793339264d4f4cbd027233f50fa5df,

title = "Alpha backgrounds in the AMoRE-Pilot experiment",

abstract = "The Advanced Mo-based Rare process Experiment (AMoRE)-Pilot experiment is an initial phase of the AMoRE search for neutrinoless double beta decay of 100Mo, with the purpose of investigating the level and sources of backgrounds. Searches for neutrinoless double beta decay generally require ultimately low backgrounds. Surface α decays on the crystals themselves or nearby materials can deposit a continuum of energies that can be as high as the Q-value of the decay itself and may fall in the region of interest (ROI). To understand these background events, we studied backgrounds from radioactive contaminations internal to and on the surface of the crystals or nearby materials with Geant4-based Monte Carlo simulations. In this study, we report on the measured α energy spectra fitted with the corresponding simulated spectra for six crystal detectors, where sources of background contributions could be identified through high energy α peaks and continuum parts in the energy spectrum for both internal and surface contaminations. We determine the low-energy contributions from internal and surface α contaminations by extrapolating from the α background fitting model.",

author = "V. Alenkov and Bae, {H. W.} and J. Beyer and Boiko, {R. S.} and K. Boonin and O. Buzanov and N. Chanthima and Cheoun, {M. K.} and Choi, {S. H.} and Danevich, {F. A.} and M. Djamal and D. Drung and C. Enss and A. Fleischmann and A. Gangapshev and L. Gastaldo and Gavriljuk, {Yu M.} and A. Gezhaev and Grigoryeva, {V. D.} and V. Gurentsov and Ha, {D. H.} and C. Ha and Ha, {E. J.} and I. Hahn and Jeon, {E. J.} and J. Jeon and Jo, {H. S.} and J. Kaewkhao and Kang, {C. S.} and Kang, {S. J.} and Kang, {W. G.} and S. Karki and V. Kazalov and A. Khan and S. Khan and Kim, {D. Y.} and Kim, {G. W.} and Kim, {H. B.} and Kim, {H. J.} and Kim, {H. L.} and Kim, {H. S.} and I. Kim and Kim, {W. T.} and Kim, {S. R.} and Kim, {S. C.} and Kim, {S. K.} and Kim, {Y. D.} and Kim, {Y. H.} and K. Kirdsiri and Ko, {Y. J.} and Kobychev, {V. V.} and V. Kornoukhov and V. Kuz{\textquoteright}minov and Kwon, {D. H.} and C. Lee and Lee, {E. K.} and Lee, {H. J.} and Lee, {H. S.} and J. Lee and Lee, {J. S.} and Lee, {J. Y.} and Lee, {K. B.} and Lee, {M. H.} and Lee, {M. K.} and Lee, {S. H.} and Lee, {S. W.} and Lee, {S. W.} and Leonard, {D. S.} and J. Li and Y. Li and P. Limkitjaroenporn and B. Mailyan and Makarov, {E. P.} and Oh, {S. Y.} and Oh, {Y. M.} and O. Gileva and S. Olsen and A. Pabitra and S. Panasenko and I. Pandey and Park, {C. W.} and Park, {H. K.} and Park, {H. S.} and Park, {K. S.} and Park, {S. Y.} and Polischuk, {O. G.} and H. Prihtiadi and Ra, {S. J.} and S. Ratkevich and G. Rooh and Sari, {M. B.} and J. Seo and Seo, {K. M.} and Shin, {J. W.} and Shin, {K. A.} and Shlegel, {V. N.} and K. Siyeon and Sokur, {N. V.} and Son, {J. K.} and N. Srisittipokakun and N. Toibaev and Tretyak, {V. I.} and R. Wirawan and Woo, {K. R.} and Yoon, {Y. S.} and Q. Yue",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s).",

year = "2022",

month = dec,

doi = "10.1140/epjc/s10052-022-11104-3",

language = "English",

volume = "82",

journal = "European Physical Journal C",

issn = "1434-6044",

publisher = "Springer Nature",

number = "12",

}

Alenkov, V, Bae, HW, Beyer, J, Boiko, RS, Boonin, K, Buzanov, O, Chanthima, N, Cheoun, MK, Choi, SH, Danevich, FA, Djamal, M, Drung, D, Enss, C, Fleischmann, A, Gangapshev, A, Gastaldo, L, Gavriljuk, YM, Gezhaev, A, Grigoryeva, VD, Gurentsov, V, Ha, DH, Ha, C, Ha, EJ, Hahn, I, Jeon, EJ, Jeon, J, Jo, HS, Kaewkhao, J, Kang, CS, Kang, SJ, Kang, WG, Karki, S, Kazalov, V, Khan, A, Khan, S, Kim, DY, Kim, GW, Kim, HB, Kim, HJ, Kim, HL, Kim, HS, Kim, I, Kim, WT, Kim, SR, Kim, SC, Kim, SK, Kim, YD, Kim, YH, Kirdsiri, K, Ko, YJ, Kobychev, VV, Kornoukhov, V, Kuz’minov, V, Kwon, DH, Lee, C, Lee, EK, Lee, HJ, Lee, HS, Lee, J, Lee, JS, Lee, JY, Lee, KB, Lee, MH, Lee, MK, Lee, SH, Lee, SW, Lee, SW, Leonard, DS, Li, J, Li, Y, Limkitjaroenporn, P, Mailyan, B, Makarov, EP, Oh, SY, Oh, YM, Gileva, O, Olsen, S, Pabitra, A, Panasenko, S, Pandey, I, Park, CW, Park, HK, Park, HS, Park, KS, Park, SY, Polischuk, OG, Prihtiadi, H, Ra, SJ, Ratkevich, S, Rooh, G, Sari, MB, Seo, J, Seo, KM, Shin, JW, Shin, KA, Shlegel, VN, Siyeon, K, Sokur, NV, Son, JK, Srisittipokakun, N, Toibaev, N, Tretyak, VI, Wirawan, R, Woo, KR, Yoon, YS & Yue, Q 2022, 'Alpha backgrounds in the AMoRE-Pilot experiment', European Physical Journal C, vol. 82, no. 12, 1140. https://doi.org/10.1140/epjc/s10052-022-11104-3

TY - JOUR

T1 - Alpha backgrounds in the AMoRE-Pilot experiment

AU - Alenkov, V.

AU - Bae, H. W.

AU - Beyer, J.

AU - Boiko, R. S.

AU - Boonin, K.

AU - Buzanov, O.

AU - Chanthima, N.

AU - Cheoun, M. K.

AU - Choi, S. H.

AU - Danevich, F. A.

AU - Djamal, M.

AU - Drung, D.

AU - Enss, C.

AU - Fleischmann, A.

AU - Gangapshev, A.

AU - Gastaldo, L.

AU - Gavriljuk, Yu M.

AU - Gezhaev, A.

AU - Grigoryeva, V. D.

AU - Gurentsov, V.

AU - Ha, D. H.

AU - Ha, C.

AU - Ha, E. J.

AU - Hahn, I.

AU - Jeon, E. J.

AU - Jeon, J.

AU - Jo, H. S.

AU - Kaewkhao, J.

AU - Kang, C. S.

AU - Kang, S. J.

AU - Kang, W. G.

AU - Karki, S.

AU - Kazalov, V.

AU - Khan, A.

AU - Khan, S.

AU - Kim, D. Y.

AU - Kim, G. W.

AU - Kim, H. B.

AU - Kim, H. J.

AU - Kim, H. L.

AU - Kim, H. S.

AU - Kim, I.

AU - Kim, W. T.

AU - Kim, S. R.

AU - Kim, S. C.

AU - Kim, S. K.

AU - Kim, Y. D.

AU - Kim, Y. H.

AU - Kirdsiri, K.

AU - Ko, Y. J.

AU - Kobychev, V. V.

AU - Kornoukhov, V.

AU - Kuz’minov, V.

AU - Kwon, D. H.

AU - Lee, C.

AU - Lee, E. K.

AU - Lee, H. J.

AU - Lee, H. S.

AU - Lee, J.

AU - Lee, J. S.

AU - Lee, J. Y.

AU - Lee, K. B.

AU - Lee, M. H.

AU - Lee, M. K.

AU - Lee, S. H.

AU - Lee, S. W.

AU - Leonard, D. S.

AU - Li, J.

AU - Li, Y.

AU - Limkitjaroenporn, P.

AU - Mailyan, B.

AU - Makarov, E. P.

AU - Oh, S. Y.

AU - Oh, Y. M.

AU - Gileva, O.

AU - Olsen, S.

AU - Pabitra, A.

AU - Panasenko, S.

AU - Pandey, I.

AU - Park, C. W.

AU - Park, H. K.

AU - Park, H. S.

AU - Park, K. S.

AU - Park, S. Y.

AU - Polischuk, O. G.

AU - Prihtiadi, H.

AU - Ra, S. J.

AU - Ratkevich, S.

AU - Rooh, G.

AU - Sari, M. B.

AU - Seo, J.

AU - Seo, K. M.

AU - Shin, J. W.

AU - Shin, K. A.

AU - Shlegel, V. N.

AU - Siyeon, K.

AU - Sokur, N. V.

AU - Son, J. K.

AU - Srisittipokakun, N.

AU - Toibaev, N.

AU - Tretyak, V. I.

AU - Wirawan, R.

AU - Woo, K. R.

AU - Yoon, Y. S.

AU - Yue, Q.

PY - 2022/12

Y1 - 2022/12

N2 - The Advanced Mo-based Rare process Experiment (AMoRE)-Pilot experiment is an initial phase of the AMoRE search for neutrinoless double beta decay of 100Mo, with the purpose of investigating the level and sources of backgrounds. Searches for neutrinoless double beta decay generally require ultimately low backgrounds. Surface α decays on the crystals themselves or nearby materials can deposit a continuum of energies that can be as high as the Q-value of the decay itself and may fall in the region of interest (ROI). To understand these background events, we studied backgrounds from radioactive contaminations internal to and on the surface of the crystals or nearby materials with Geant4-based Monte Carlo simulations. In this study, we report on the measured α energy spectra fitted with the corresponding simulated spectra for six crystal detectors, where sources of background contributions could be identified through high energy α peaks and continuum parts in the energy spectrum for both internal and surface contaminations. We determine the low-energy contributions from internal and surface α contaminations by extrapolating from the α background fitting model.

AB - The Advanced Mo-based Rare process Experiment (AMoRE)-Pilot experiment is an initial phase of the AMoRE search for neutrinoless double beta decay of 100Mo, with the purpose of investigating the level and sources of backgrounds. Searches for neutrinoless double beta decay generally require ultimately low backgrounds. Surface α decays on the crystals themselves or nearby materials can deposit a continuum of energies that can be as high as the Q-value of the decay itself and may fall in the region of interest (ROI). To understand these background events, we studied backgrounds from radioactive contaminations internal to and on the surface of the crystals or nearby materials with Geant4-based Monte Carlo simulations. In this study, we report on the measured α energy spectra fitted with the corresponding simulated spectra for six crystal detectors, where sources of background contributions could be identified through high energy α peaks and continuum parts in the energy spectrum for both internal and surface contaminations. We determine the low-energy contributions from internal and surface α contaminations by extrapolating from the α background fitting model.

UR - http://www.scopus.com/inward/record.url?scp=85144094615&partnerID=8YFLogxK

U2 - 10.1140/epjc/s10052-022-11104-3

DO - 10.1140/epjc/s10052-022-11104-3

M3 - Article

AN - SCOPUS:85144094615

SN - 1434-6044

VL - 82

JO - European Physical Journal C

JF - European Physical Journal C

IS - 12

M1 - 1140

ER -

Alpha backgrounds in the AMoRE-Pilot experiment

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