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1. Search for double-beta decay of $$\mathrm {^{130}Te}$$ 130 Te to the $$0^+$$ 0 + states of $$\mathrm {^{130}Xe}$$ 130 Xe with CUORE

Author

D. Q. Adams, C. Alduino, K. Alfonso, F. T. III Avignone, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, E. Celi, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D’Addabbo, I. Dafinei, C. J. Davis, S. Dell’Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, S. H. Fu, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, D. Mayer, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, A. Nucciotti, I. Nutini, T. O’Donnell, J. L. Ouellet, S. Pagan, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Sharma, V. Singh, M. Sisti, D. Speller, P. T. Surukuchi, L. Taffarello, F. Terranova, C. Tomei, K. J. Vetter, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, S. Zimmermann, and S. Zucchelli

Subjects
Astrophysics, QB460-466, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798
Abstract

Abstract The CUORE experiment is a large bolometric array searching for the lepton number violating neutrino-less double beta decay ( $$0\nu \beta \beta $$ 0 ν β β ) in the isotope $$\mathrm {^{130}Te}$$ 130 Te . In this work we present the latest results on two searches for the double beta decay (DBD) of $$\mathrm {^{130}Te}$$ 130 Te to the first $$0^{+}_2$$ 0 2 + excited state of $$\mathrm {^{130}Xe}$$ 130 Xe : the $$0\nu \beta \beta $$ 0 ν β β decay and the Standard Model-allowed two-neutrinos double beta decay ( $$2\nu \beta \beta $$ 2 ν β β ). Both searches are based on a 372.5 kg $$\times $$ × yr TeO $$_2$$ 2 exposure. The de-excitation gamma rays emitted by the excited Xe nucleus in the final state yield a unique signature, which can be searched for with low background by studying coincident events in two or more bolometers. The closely packed arrangement of the CUORE crystals constitutes a significant advantage in this regard. The median limit setting sensitivities at 90% Credible Interval (C.I.) of the given searches were estimated as $$\mathrm {S^{0\nu }_{1/2} = 5.6 \times 10^{24} \, \mathrm {yr}}$$ S 1 / 2 0 ν = 5.6 × 10 24 yr for the $${0\nu \beta \beta }$$ 0 ν β β decay and $$\mathrm {S^{2\nu }_{1/2} = 2.1 \times 10^{24} \, \mathrm {yr}}$$ S 1 / 2 2 ν = 2.1 × 10 24 yr for the $${2\nu \beta \beta }$$ 2 ν β β decay. No significant evidence for either of the decay modes was observed and a Bayesian lower bound at $$90\%$$ 90 % C.I. on the decay half lives is obtained as: $$\mathrm {(T_{1/2})^{0\nu }_{0^+_2} > 5.9 \times 10^{24} \, \mathrm {yr}}$$ ( T 1 / 2 ) 0 2 + 0 ν > 5.9 × 10 24 yr for the $$0\nu \beta \beta $$ 0 ν β β mode and $$\mathrm {(T_{1/2})^{2\nu }_{0^+_2} > 1.3 \times 10^{24} \, \mathrm {yr}}$$ ( T 1 / 2 ) 0 2 + 2 ν > 1.3 × 10 24 yr for the $$2\nu \beta \beta $$ 2 ν β β mode. These represent the most stringent limits on the DBD of $$^{130}$$ 130 Te to excited states and improve by a factor $$\sim 5$$ ∼ 5 the previous results on this process.

Published
2021
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2. Double-beta decay of $$^{130}\hbox {Te}$$ 130Te to the first $$0^+$$ 0+ excited state of $$^{130}\hbox {Xe}$$ 130Xe with CUORE-0

Author

C. Alduino, K. Alfonso, D. R. Artusa, F. T. Avignone III, O. Azzolini, T. I. Banks, G. Bari, J. W. Beeman, F. Bellini, A. Bersani, M. Biassoni, C. Brofferio, C. Bucci, A. Camacho, A. Caminata, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Carbone, L. Cardani, P. Carniti, N. Casali, L. Cassina, D. Chiesa, N. Chott, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, J. S. Cushman, A. D’Addabbo, I. Dafinei, C. J. Davis, S. Dell’Oro, M. M. Deninno, S. Di Domizio, M. L. Di Vacri, A. Drobizhev, D. Q. Fang, M. Faverzani, J. Feintzeig, G. Fernandes, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, L. Gladstone, P. Gorla, C. Gotti, T. D. Gutierrez, E. E. Haller, K. Han, E. Hansen, K. M. Heeger, R. Hennings-Yeomans, K. P. Hickerson, H. Z. Huang, R. Kadel, G. Keppel, Yu. G. Kolomensky, A. Leder, C. Ligi, K. E. Lim, X. Liu, Y. G. Ma, M. Maino, L. Marini, M. Martinez, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, P. J. Mosteiro, T. Napolitano, C. Nones, E. B. Norman, A. Nucciotti, T. O’Donnell, F. Orio, J. L. Ouellet, C. E. Pagliarone, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, G. Piperno, C. Pira, S. Pirro, S. Pozzi, E. Previtali, C. Rosenfeld, C. Rusconi, S. Sangiorgio, D. Santone, N. D. Scielzo, V. Singh, M. Sisti, A. R. Smith, L. Taffarello, M. Tenconi, F. Terranova, C. Tomei, S. Trentalange, M. Vignati, S. L. Wagaarachchi, B. S. Wang, H. W. Wang, J. Wilson, L. A. Winslow, T. Wise, A. Woodcraft, L. Zanotti, G. Q. Zhang, B. X. Zhu, S. Zimmermann, and S. Zucchelli

Subjects
Astrophysics, QB460-466, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798
Abstract

Abstract We report on a search for double beta decay of $$^{130}\hbox {Te}$$ 130Te to the first $$0^{+}$$ 0+ excited state of $$^{130}\hbox {Xe}$$ 130Xe using a $$9.8\,\hbox {kg}\cdot \hbox {yr}$$ 9.8kg·yr exposure of $$^{130}\hbox {Te}$$ 130Te collected with the CUORE-0 experiment. In this work we exploit different topologies of coincident events to search for both the neutrinoless and two-neutrino double beta decay modes. We find no evidence for either mode and place lower bounds on the half-lives: $$T^{0\nu }_{0^+_1}>7.9\cdot 10^{23}\hbox {yr}$$ T01+0ν>7.9·1023yr and $$T^{2\nu }_{0^+_1}>2.4\cdot 10^{23}\hbox {yr}$$ T01+2ν>2.4·1023yr ($$90\%\,\hbox {CL}$$ 90%CL ). Combining our results with those obtained by the CUORICINO experiment, we achieve the most stringent constraints available for these processes: $$T^{0\nu }_{0^+_1}>1.4\cdot 10^{24}\hbox {yr}$$ T01+0ν>1.4·1024yr and $$T^{2\nu }_{0^+_1}>2.5\cdot 10^{23}\hbox {yr}$$ T01+2ν>2.5·1023yr ($$90\%\,\hbox {CL}$$ 90%CL ).

Published
2019
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3. Low energy analysis techniques for CUORE

Author

C. Alduino, K. Alfonso, D. R. Artusa, F. T. Avignone, O. Azzolini, G. Bari, J. W. Beeman, F. Bellini, G. Benato, A. Bersani, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, A. Camacho, A. Caminata, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, L. Cassina, D. Chiesa, N. Chott, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, J. S. Cushman, A. D’Addabbo, D. D’Aguanno, I. Dafinei, C. J. Davis, S. Dell’Oro, M. M. Deninno, S. Di Domizio, M. L. Di Vacri, A. Drobizhev, D. Q. Fang, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, L. Gladstone, P. Gorla, C. Gotti, T. D. Gutierrez, E. E. Haller, K. Han, E. Hansen, K. M. Heeger, R. Hennings-Yeomans, H. Z. Huang, R. Kadel, G. Keppel, Yu. G. Kolomensky, A. Leder, C. Ligi, K. E. Lim, Y. G. Ma, M. Maino, L. Marini, M. Martinez, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, P. J. Mosteiro, T. Napolitano, M. Nastasi, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, T. O’Donnell, J. L. Ouellet, C. E. Pagliarone, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, G. Pessina, G. Piperno, C. Pira, S. Pirro, S. Pozzi, E. Previtali, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, D. Santone, B. Schmidt, J. Schmidt, N. D. Scielzo, V. Singh, M. Sisti, A. R. Smith, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, H. W. Wang, B. Welliver, J. Wilson, L. A. Winslow, T. Wise, A. Woodcraft, L. Zanotti, G. Q. Zhang, S. Zimmermann, and S. Zucchelli

Subjects
Astrophysics, QB460-466, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798
Abstract

Abstract CUORE is a tonne-scale cryogenic detector operating at the Laboratori Nazionali del Gran Sasso (LNGS) that uses tellurium dioxide bolometers to search for neutrinoless double-beta decay of $$^{130}$$ 130 Te. CUORE is also suitable to search for low energy rare events such as solar axions or WIMP scattering, thanks to its ultra-low background and large target mass. However, to conduct such sensitive searches requires improving the energy threshold to 10 keV. In this paper, we describe the analysis techniques developed for the low energy analysis of CUORE-like detectors, using the data acquired from November 2013 to March 2015 by CUORE-0, a single-tower prototype designed to validate the assembly procedure and new cleaning techniques of CUORE. We explain the energy threshold optimization, continuous monitoring of the trigger efficiency, data and event selection, and energy calibration at low energies in detail. We also present the low energy background spectrum of CUORE-0 below $$60 \, \mathrm {keV}$$ 60 keV . Finally, we report the sensitivity of CUORE to WIMP annual modulation using the CUORE-0 energy threshold and background, as well as an estimate of the uncertainty on the nuclear quenching factor from nuclear recoils inCUORE-0.

Published
2017
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4. The projected background for the CUORE experiment

Author

C. Alduino, K. Alfonso, D. R. Artusa, F. T. Avignone, O. Azzolini, T. I. Banks, G. Bari, J. W. Beeman, F. Bellini, G. Benato, A. Bersani, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, A. Camacho, A. Caminata, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Carbone, L. Cardani, P. Carniti, N. Casali, L. Cassina, D. Chiesa, N. Chott, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, J. S. Cushman, A. D’Addabbo, I. Dafinei, C. J. Davis, S. Dell’Oro, M. M. Deninno, S. Di Domizio, M. L. Di Vacri, A. Drobizhev, D. Q. Fang, M. Faverzani, G. Fernandes, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, L. Gladstone, P. Gorla, C. Gotti, T. D. Gutierrez, E. E. Haller, K. Han, E. Hansen, K. M. Heeger, R. Hennings-Yeomans, K. P. Hickerson, H. Z. Huang, R. Kadel, G. Keppel, Yu. G. Kolomensky, A. Leder, C. Ligi, K. E. Lim, Y. G. Ma, M. Maino, L. Marini, M. Martinez, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, P. J. Mosteiro, T. Napolitano, M. Nastasi, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, T. O’Donnell, J. L. Ouellet, C. E. Pagliarone, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, G. Piperno, C. Pira, S. Pirro, S. Pozzi, E. Previtali, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, D. Santone, B. Schmidt, J. Schmidt, N. D. Scielzo, V. Singh, M. Sisti, A. R. Smith, L. Taffarello, M. Tenconi, F. Terranova, C. Tomei, S. Trentalange, M. Vignati, S. L. Wagaarachchi, B. S. Wang, H. W. Wang, B. Welliver, J. Wilson, L. A. Winslow, T. Wise, A. Woodcraft, L. Zanotti, G. Q. Zhang, B. X. Zhu, S. Zimmermann, S. Zucchelli, and M. Laubenstein

Subjects
Astrophysics, QB460-466, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798
Abstract

Abstract The Cryogenic Underground Observatory for Rare Events (CUORE) is designed to search for neutrinoless double beta decay of $$^{130}$$ 130 Te with an array of 988 TeO $$_2$$ 2 bolometers operating at temperatures around 10 mK. The experiment is currently being commissioned in Hall A of Laboratori Nazionali del Gran Sasso, Italy. The goal of CUORE is to reach a 90% C.L. exclusion sensitivity on the $$^{130}$$ 130 Te decay half-life of 9 $$\times $$ × 10 $$^{25}$$ 25 years after 5 years of data taking. The main issue to be addressed to accomplish this aim is the rate of background events in the region of interest, which must not be higher than 10 $$^{-2}$$ - 2 counts/keV/kg/year. We developed a detailed Monte Carlo simulation, based on results from a campaign of material screening, radioassays, and bolometric measurements, to evaluate the expected background. This was used over the years to guide the construction strategies of the experiment and we use it here to project a background model for CUORE. In this paper we report the results of our study and our expectations for the background rate in the energy region where the peak signature of neutrinoless double beta decay of $$^{130}$$ 130 Te is expected.

Published
2017
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5. CUORE sensitivity to $$0\nu \beta \beta $$ 0 ν β β decay

Author

C. Alduino, K. Alfonso, D. R. Artusa, F. T. Avignone, O. Azzolini, T. I. Banks, G. Bari, J. W. Beeman, F. Bellini, G. Benato, A. Bersani, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, A. Camacho, A. Caminata, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Carbone, L. Cardani, P. Carniti, N. Casali, L. Cassina, D. Chiesa, N. Chott, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, J. S. Cushman, A. D’Addabbo, I. Dafinei, C. J. Davis, S. Dell’Oro, M. M. Deninno, S. Di Domizio, M. L. Di Vacri, A. Drobizhev, D. Q. Fang, M. Faverzani, G. Fernandes, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, L. Gladstone, P. Gorla, C. Gotti, T. D. Gutierrez, E. E. Haller, K. Han, E. Hansen, K. M. Heeger, R. Hennings-Yeomans, K. P. Hickerson, H. Z. Huang, R. Kadel, G. Keppel, Yu. G. Kolomensky, A. Leder, C. Ligi, K. E. Lim, Y. G. Ma, M. Maino, L. Marini, M. Martinez, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, P. J. Mosteiro, T. Napolitano, M. Nastasi, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, T. O’Donnell, J. L. Ouellet, C. E. Pagliarone, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, G. Piperno, C. Pira, S. Pirro, S. Pozzi, E. Previtali, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, D. Santone, B. Schmidt, J. Schmidt, N. D. Scielzo, V. Singh, M. Sisti, A. R. Smith, L. Taffarello, M. Tenconi, F. Terranova, C. Tomei, S. Trentalange, M. Vignati, S. L. Wagaarachchi, B. S. Wang, H. W. Wang, B. Welliver, J. Wilson, L. A. Winslow, T. Wise, A. Woodcraft, L. Zanotti, G. Q. Zhang, B. X. Zhu, S. Zimmermann, and S. Zucchelli

Subjects
Astrophysics, QB460-466, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798
Abstract

Abstract We report a study of the CUORE sensitivity to neutrinoless double beta ( $$0\nu \beta \beta $$ 0 ν β β ) decay. We used a Bayesian analysis based on a toy Monte Carlo (MC) approach to extract the exclusion sensitivity to the $$0\nu \beta \beta $$ 0 ν β β decay half-life ( $$T_{1/2}^{\,0\nu }$$ T 1 / 2 0 ν ) at $$90\%$$ 90 % credibility interval (CI) – i.e. the interval containing the true value of $$T_{1/2}^{\,0\nu }$$ T 1 / 2 0 ν with $$90\%$$ 90 % probability – and the $$3~\sigma $$ 3 σ discovery sensitivity. We consider various background levels and energy resolutions, and describe the influence of the data division in subsets with different background levels. If the background level and the energy resolution meet the expectation, CUORE will reach a $$90\%$$ 90 % CI exclusion sensitivity of $$2\cdot 10^{25}$$ 2 · 10 25 year with 3 months, and $$9\cdot 10^{25}$$ 9 · 10 25 year with 5 years of live time. Under the same conditions, the discovery sensitivity after 3 months and 5 years will be $$7\cdot 10^{24}$$ 7 · 10 24 year and $$4\cdot 10^{25}$$ 4 · 10 25 year, respectively.

Published
2017
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6. Searching for Neutrinoless Double-Beta Decay of 130Te with CUORE

Author

D. R. Artusa, F. T. Avignone, O. Azzolini, M. Balata, T. I. Banks, G. Bari, J. Beeman, F. Bellini, A. Bersani, M. Biassoni, C. Brofferio, C. Bucci, X. Z. Cai, A. Camacho, L. Canonica, X. G. Cao, S. Capelli, L. Carbone, L. Cardani, M. Carrettoni, N. Casali, D. Chiesa, N. Chott, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, I. Dafinei, A. Dally, V. Datskov, A. De Biasi, M. M. Deninno, S. Di Domizio, M. L. di Vacri, L. Ejzak, D. Q. Fang, H. A. Farach, M. Faverzani, G. Fernandes, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, J. Goett, P. Gorla, C. Gotti, T. D. Gutierrez, E. E. Haller, K. Han, K. M. Heeger, R. Hennings-Yeomans, H. Z. Huang, R. Kadel, K. Kazkaz, G. Keppel, Yu. G. Kolomensky, Y. L. Li, C. Ligi, X. Liu, Y. G. Ma, C. Maiano, M. Maino, M. Martinez, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, S. Nisi, C. Nones, E. B. Norman, A. Nucciotti, T. O’Donnell, F. Orio, D. Orlandi, J. L. Ouellet, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, M. Pedretti, G. Pessina, V. Pettinacci, G. Piperno, C. Pira, S. Pirro, E. Previtali, V. Rampazzo, C. Rosenfeld, C. Rusconi, E. Sala, S. Sangiorgio, N. D. Scielzo, M. Sisti, A. R. Smith, L. Taffarello, M. Tenconi, F. Terranova, W. D. Tian, C. Tomei, S. Trentalange, G. Ventura, M. Vignati, B. S. Wang, H. W. Wang, L. Wielgus, J. Wilson, L. A. Winslow, T. Wise, A. Woodcraft, L. Zanotti, C. Zarra, B. X. Zhu, and S. Zucchelli

Subjects
Physics, QC1-999
Abstract

Neutrinoless double-beta (0νββ) decay is a hypothesized lepton-number-violating process that offers the only known means of asserting the possible Majorana nature of neutrino mass. The Cryogenic Underground Observatory for Rare Events (CUORE) is an upcoming experiment designed to search for 0νββ decay of 130Te using an array of 988 TeO2 crystal bolometers operated at 10 mK. The detector will contain 206 kg of 130Te and have an average energy resolution of 5 keV; the projected 0νββ decay half-life sensitivity after five years of livetime is 1.6 × 1026 y at 1σ (9.5 × 1025 y at the 90% confidence level), which corresponds to an upper limit on the effective Majorana mass in the range 40–100 meV (50–130 meV). In this paper, we review the experimental techniques used in CUORE as well as its current status and anticipated physics reach.

Published
2015
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7. Perspectives of lowering CUORE thresholds with Optimum Trigger

Author

Monica Sisti, A. Bersani, C. Brofferio, G. Fantini, A. Caminata, Marco Pallavicini, B. Welliver, C. Pagliarone, R. G. Huang, M. Faverzani, Y. u. G. Kolomensky, H. Z. Huang, G. Keppel, Massimiliano Nastasi, Yudi Ma, S. Pozzi, S. L. Wagaarachchi, C. Cosmelli, A. Giuliani, C. Pira, C. Rusconi, Ke Han, A. Branca, N. D. Scielzo, Reina H. Maruyama, N. Casali, Stefano Dell'Oro, Lucia Canonica, F. Bellini, I. Dafinei, V. Novati, T. Wise, V. Pettinacci, Davide Chiesa, Stefano Zucchelli, Laura Cardani, L. Gironi, M. Pavan, B. K. Fujikawa, Y. Mei, V. Singh, D. D'Aguanno, F. T. Avignone, L. Taffarello, R. J. Creswick, C. Rosenfeld, P. Gorla, Danielle Speller, F. Ferroni, C. Tomei, M. Vignati, E. Previtali, Simone Capelli, D. Q. Adams, L. Marini, C. J. Davis, K. Alfonso, T. O'Donnell, B. Schmidt, N. Chott, C. Nones, A. Puiu, Lindley Winslow, S. Zimmermann, Oliviero Cremonesi, J. Johnston, L. Pattavina, Irene Nutini, S. Copello, C. Bucci, Miriam Lucio Martinez, Paolo Carniti, Sergio Di Domizio, S. Pirro, Xi-Guang Cao, E. Fiorini, S. J. Freedman, K. M. Heeger, Luigi Cappelli, T. D. Gutierrez, F. Terranova, K. Wilson, G. Pessina, B. S. Wang, Jonathan Ouellet, G. Bari, O. Azzolini, Evelyn Ferri, N. Moggi, Samuele Sangiorgio, A. Nucciotti, C. Alduino, Jeremy S. Cushman, S. Morganti, L. Zanotti, Carlo Ligi, A. Campani, V. Dompè, A. D'Addabbo, A. Leder, J. S. Wilson, Franceschi, Eric B. Norman, M. Sakai, T. Napolitano, M. Biassoni, Giovanni Benato, A. Drobizhev, C. Gotti, A. Giachero, D. Q. Fang, Massimiliano Clemenza, Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), and Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay

Subjects
Physics, History, CUORE, 010308 nuclear & particles physics, Physics::Instrumentation and Detectors, WIMP nucleus: scattering, trigger: programming, 01 natural sciences, Large target, tellurium: oxygen, Computer Science Applications, Education, Combinatorics, energy: threshold, Low energy, double-beta decay: (0neutrino), 0103 physical sciences, High Energy Physics::Experiment, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], 010306 general physics, activity report, energy: low
Abstract

Author(s): Dompe, V; Adams, DQ; Alduino, C; Alfonso, K; Avignone, FT; Azzolini, O; Bari, G; Bellini, F; Benato, G; Bersani, A; Biassoni, M; Branca, A; Brofferio, C; Bucci, C; Caminata, A; Campani, A; Canonica, L; Cao, XG; Capelli, S; Cappelli, L; Cardani, L; Carniti, P; Casali, N; Chiesa, D; Chott, N; Clemenza, M; Copello, S; Cosmelli, C; Cremonesi, O; Creswick, RJ; Cushman, JS; D'Addabbo, A; D'Aguanno, D; Dafinei, I; Davis, CJ; Dell'Oro, S; Domizio, SD; Drobizhev, A; Fang, DQ; Fantini, G; Faverzani, M; Ferri, E; Ferroni, F; Fiorini, E; Franceschi, MA; Freedman, SJ; Fujikawa, BK; Giachero, A; Gironi, L; Giuliani, A; Gorla, P; Gotti, C; Gutierrez, TD; Han, K; Heeger, KM; Huang, RG; Huang, HZ; Johnston, J; Keppel, G; Kolomensky, YG; Leder, A; Ligi, C; Ma, YG; Marini, L; Martinez, M; Maruyama, RH; Mei, Y; Moggi, N; Morganti, S; Napolitano, T; Nastasi, M; Nones, C; Norman, EB; Novati, V; Nucciotti, A; Nutini, I; O'Donnell, T; Ouellet, JL; Pagliarone, CE; Pallavicini, M; Pattavina, L; Pavan, M; Pessina, G; Pettinacci, V; Pira, C | Abstract: CUORE is a cryogenic experiment that focuses on the search of neutrinoless double beta decay in 130Te and it is located at the Gran Sasso National Laboratories. Its detector consists of 988 TeO2 crystals operating at a base temperature of ∼10 mK. It is the first ton-scale bolometric experiment ever realized for this purpose. Thanks to its large target mass and ultra-low background, the CUORE detector is also suitable for the search of other rare phenomena. In particular the low energy part of the spectra is interesting for the detection of WIMP-nuclei scattering reactions. One of the most important requirements to perform these studies is represented by the achievement of a stable energy threshold lower than 10 keV. Here, the CUORE capability to accomplish this purpose using a low energy software trigger will be presented and described.

Published
2020

8. Results from the CUORE experiment

Author

D. Q. Adams, C. Alduino, K. Alfonso, F. T. Avignone III, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D'Addabbo, D. D'Aguanno, I. Dafinei, C. J. Davis, F. Del Corso, S. Dell'Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, I. Nutini, T. O'Donnell, J. L. Ouellet, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Singh, M. Sisti, D. Speller, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, L. Zanotti, S. Zimmermann, S. Zucchelli, Adams, D, Alduino, C, Alfonso, K, Avignone III, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Biassoni, M, Branca, A, Brofferio, C, Bucci, C, Camilleri, J, Caminata, A, Campani, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Chiesa, D, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Del Corso, F, Dell'Oro, S, Di Domizio, S, Dompè, V, Fang, D, Fantini, G, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Huang, R, Huang, H, Johnston, J, Keppel, G, Kolomensky, Y, Ligi, C, Ma, L, Ma, Y, Marini, L, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nastasi, M, Nikkel, J, Nones, C, Norman, E, Novati, V, Nucciotti, A, Nutini, I, O'Donnell, T, Ouellet, J, Pagliarone, C, Pagnanini, L, Pallavicini, M, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Puiu, A, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Schmidt, B, Scielzo, N, Singh, V, Sisti, M, Speller, D, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Welliver, B, Wilson, J, Wilson, K, Winslow, L, Zanotti, L, Zimmermann, S, and Zucchelli, S

Subjects
neutrinoless double beta decay
Published
2020

9. Results from the CUORE experiment

Author

Adams, D, Alduino, C, Alfonso, K, Avignone III, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Biassoni, M, Branca, A, Brofferio, C, Bucci, C, Camilleri, J, Caminata, A, Campani, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Chiesa, D, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Del Corso, F, Dell'Oro, S, Di Domizio, S, Dompè, V, Fang, D, Fantini, G, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Huang, R, Huang, H, Johnston, J, Keppel, G, Kolomensky, Y, Ligi, C, Ma, L, Ma, Y, Marini, L, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nastasi, M, Nikkel, J, Nones, C, Norman, E, Novati, V, Nucciotti, A, Nutini, I, O'Donnell, T, Ouellet, J, Pagliarone, C, Pagnanini, L, Pallavicini, M, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Puiu, A, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Schmidt, B, Scielzo, N, Singh, V, Sisti, M, Speller, D, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Welliver, B, Wilson, J, Wilson, K, Winslow, L, Zanotti, L, Zimmermann, S, Zucchelli, S, D. Q. Adams, C. Alduino, K. Alfonso, F. T. Avignone III, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D'Addabbo, D. D'Aguanno, I. Dafinei, C. J. Davis, F. Del Corso, S. Dell'Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, I. Nutini, T. O'Donnell, J. L. Ouellet, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Singh, M. Sisti, D. Speller, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, L. Zanotti, S. Zimmermann, S. Zucchelli, Adams, D, Alduino, C, Alfonso, K, Avignone III, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Biassoni, M, Branca, A, Brofferio, C, Bucci, C, Camilleri, J, Caminata, A, Campani, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Chiesa, D, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Del Corso, F, Dell'Oro, S, Di Domizio, S, Dompè, V, Fang, D, Fantini, G, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Huang, R, Huang, H, Johnston, J, Keppel, G, Kolomensky, Y, Ligi, C, Ma, L, Ma, Y, Marini, L, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nastasi, M, Nikkel, J, Nones, C, Norman, E, Novati, V, Nucciotti, A, Nutini, I, O'Donnell, T, Ouellet, J, Pagliarone, C, Pagnanini, L, Pallavicini, M, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Puiu, A, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Schmidt, B, Scielzo, N, Singh, V, Sisti, M, Speller, D, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Welliver, B, Wilson, J, Wilson, K, Winslow, L, Zanotti, L, Zimmermann, S, Zucchelli, S, D. Q. Adams, C. Alduino, K. Alfonso, F. T. Avignone III, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, A. Branca, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D'Addabbo, D. D'Aguanno, I. Dafinei, C. J. Davis, F. Del Corso, S. Dell'Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, I. Nutini, T. O'Donnell, J. L. Ouellet, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Singh, M. Sisti, D. Speller, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, L. Zanotti, S. Zimmermann, and S. Zucchelli

Published
2020

10. Performance of the low threshold Optimum Trigger on CUORE data

Author

Branca, A, Adams, D, Alduino, C, Alfonso, K, Avignone III, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Biassoni, M, Brofferio, C, Bucci, C, Camilleri, J, Caminata, A, Campani, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Chiesa, D, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Del Corso, F, Dell'Oro, S, Di Domizio, S, Dompè, V, Fang, D, Fantini, G, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Huang, R, Huang, H, Johnston, J, Keppel, G, Kolomensky, Y, Ligi, C, Ma, L, Ma, Y, Marini, L, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nastasi, M, Nikkel, J, Nones, C, Norman, E, Novati, V, Nucciotti, A, Nutini, I, O'Donnell, T, Ouellet, J, Pagliarone, C, Pagnanini, L, Pallavicini, M, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Puiu, A, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Schmidt, B, Scielzo, N, Sharma, V, Singh, V, Sisti, M, Speller, D, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Welliver, B, Wilson, J, Wilson, K, Winslow, L, Zanotti, L, Zimmermann, S, Zucchelli, S, A. Branca, D. Q. Adams, C. Alduino, K. Alfonso, F. T. Avignone III, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D'Addabbo, D. D'Aguanno, I. Dafinei, C. J. Davis, F. Del Corso, S. Dell'Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, I. Nutini, T. O'Donnell, J. L. Ouellet, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Sharma, V. Singh, M. Sisti, D. Speller, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, L. Zanotti, S. Zimmermann, S. Zucchelli, Branca, A, Adams, D, Alduino, C, Alfonso, K, Avignone III, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Biassoni, M, Brofferio, C, Bucci, C, Camilleri, J, Caminata, A, Campani, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Chiesa, D, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Del Corso, F, Dell'Oro, S, Di Domizio, S, Dompè, V, Fang, D, Fantini, G, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Huang, R, Huang, H, Johnston, J, Keppel, G, Kolomensky, Y, Ligi, C, Ma, L, Ma, Y, Marini, L, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nastasi, M, Nikkel, J, Nones, C, Norman, E, Novati, V, Nucciotti, A, Nutini, I, O'Donnell, T, Ouellet, J, Pagliarone, C, Pagnanini, L, Pallavicini, M, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Puiu, A, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Schmidt, B, Scielzo, N, Sharma, V, Singh, V, Sisti, M, Speller, D, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Welliver, B, Wilson, J, Wilson, K, Winslow, L, Zanotti, L, Zimmermann, S, Zucchelli, S, A. Branca, D. Q. Adams, C. Alduino, K. Alfonso, F. T. Avignone III, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D'Addabbo, D. D'Aguanno, I. Dafinei, C. J. Davis, F. Del Corso, S. Dell'Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, I. Nutini, T. O'Donnell, J. L. Ouellet, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Sharma, V. Singh, M. Sisti, D. Speller, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, L. Zanotti, S. Zimmermann, and S. Zucchelli

Abstract

The Optimum Trigger (OT) is based on a threshold algorithm applied on waveforms filtered by exploiting the matched filter technique. The OT trigger thresholds improve by 60-90% with respect to the thresholds obtained with the standard trigger, ranging between ∼ 20 and 100 keV . Low trigger thresholds open the way to Dark Matter searches and to improvements in the neutrinoless double beta decay analysis. Nevertheless, running the OT on CUORE data is demanding from the computational resources point of view. For this reason, the algorithm has been revised and adapted to cope with CUORE data. The work done to implement OT in CUORE and its performances will be discussed.

Published
2020

11. Phonon-Mediated KIDs as Light Detectors for Rare Event Search: The CALDER Project

Author

N. Casali, I. Colantoni, F. Bellini, Laura Cardani, M. Vignati, Sergio Di Domizio, A. D'Addabbo, C. Cosmelli, Angelo Cruciani, Claudia Tomei, Maria Gabriella Castellano, and M. I. Martínez

Subjects
Photon, Dark matter, scintillating bolometer, 01 natural sciences, Noise (electronics), dark matter, neutrinoless double beta decay, Particle identification, law.invention, Nuclear physics, Kinetic inductance detector, law, Double beta decay, 0103 physical sciences, Electronic, Optical and Magnetic Materials, Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials, Condensed Matter Physics, 010306 general physics, 010303 astronomy & astrophysics, Physics, business.industry, Bolometer, Detector, Optoelectronics, Particle physics experiments, business
Abstract

Background suppression plays a crucial role in particle physics experiments searching for rare events, such as neutrinoless double beta decay and dark matter interactions. Bolometers, that are among the most competitive devices in this field, would largely benefit from the development of ultrasensitive light detectors, as the combined readout of the bolometric and light signals enables the particle identification. The CALDER collaboration is developing superconducting light detectors that will match the requirements of next generation experiments: noise lower than 20 eV, large active area (>20 cm 2 ), wide temperature range of operation, high radiopurity, and ease in fabricating hundreds of channels. For this purpose, we are exploiting the excellent energy resolution and the natural multiplexed readout provided by kinetic inductance detectors (KIDs). KIDs have already demonstrated their potentiality as direct detectors of photons for different astrophysical applications. The aim of our project is to apply this technology in particle physics, using indirect detection. These devices can be operated in a phonon-mediated approach, in which KIDs are coupled to a large insulating substrates in order to increase the active surface from a few mm2 to 25 cm 2 . We have already demonstrated the feasibility of a phonon-mediated KIDs-based light detectors, using aluminium sensors. These device reached a baseline sensitivity of around 80 eV with an overall efficiency of about 20%. Currently, we are testing new materials (e.g., Ti-Al and nonstoichiometric TiN) to enhance the sensitivity and reach the goal of our project. We present our results and the physical interpretation of the device behavior. Finally, we also discuss the impact of this project on the most advanced bolometric experiments searching for neutrinoless double beta decay and dark matter.

Published
2017

12. Performance of the low threshold Optimum Trigger on CUORE data

Author

A. Branca, D. Q. Adams, C. Alduino, K. Alfonso, F. T. Avignone III, O. Azzolini, G. Bari, F. Bellini, G. Benato, M. Biassoni, C. Brofferio, C. Bucci, J. Camilleri, A. Caminata, A. Campani, L. Canonica, X. G. Cao, S. Capelli, L. Cappelli, L. Cardani, P. Carniti, N. Casali, D. Chiesa, M. Clemenza, S. Copello, C. Cosmelli, O. Cremonesi, R. J. Creswick, A. D'Addabbo, D. D'Aguanno, I. Dafinei, C. J. Davis, F. Del Corso, S. Dell'Oro, S. Di Domizio, V. Dompè, D. Q. Fang, G. Fantini, M. Faverzani, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, T. D. Gutierrez, K. Han, K. M. Heeger, R. G. Huang, H. Z. Huang, J. Johnston, G. Keppel, Yu. G. Kolomensky, C. Ligi, L. Ma, Y. G. Ma, L. Marini, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, M. Nastasi, J. Nikkel, C. Nones, E. B. Norman, V. Novati, A. Nucciotti, I. Nutini, T. O'Donnell, J. L. Ouellet, C. E. Pagliarone, L. Pagnanini, M. Pallavicini, L. Pattavina, M. Pavan, G. Pessina, V. Pettinacci, C. Pira, S. Pirro, S. Pozzi, E. Previtali, A. Puiu, C. Rosenfeld, C. Rusconi, M. Sakai, S. Sangiorgio, B. Schmidt, N. D. Scielzo, V. Sharma, V. Singh, M. Sisti, D. Speller, L. Taffarello, F. Terranova, C. Tomei, M. Vignati, S. L. Wagaarachchi, B. S. Wang, B. Welliver, J. Wilson, K. Wilson, L. A. Winslow, L. Zanotti, S. Zimmermann, S. Zucchelli, Branca, A, Adams, D, Alduino, C, Alfonso, K, Avignone III, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Biassoni, M, Brofferio, C, Bucci, C, Camilleri, J, Caminata, A, Campani, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Chiesa, D, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Del Corso, F, Dell'Oro, S, Di Domizio, S, Dompè, V, Fang, D, Fantini, G, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Huang, R, Huang, H, Johnston, J, Keppel, G, Kolomensky, Y, Ligi, C, Ma, L, Ma, Y, Marini, L, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nastasi, M, Nikkel, J, Nones, C, Norman, E, Novati, V, Nucciotti, A, Nutini, I, O'Donnell, T, Ouellet, J, Pagliarone, C, Pagnanini, L, Pallavicini, M, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Puiu, A, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Schmidt, B, Scielzo, N, Sharma, V, Singh, V, Sisti, M, Speller, D, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Welliver, B, Wilson, J, Wilson, K, Winslow, L, Zanotti, L, Zimmermann, S, and Zucchelli, S

Subjects
Physics, History, Particle physics, CUORE, Optimal Trigger, CUORE, low energy, dark matter, WIMP, neutrino, Computer Science Applications, Education
Abstract

The Optimum Trigger (OT) is based on a threshold algorithm applied on waveforms filtered by exploiting the matched filter technique. The OT trigger thresholds improve by 60 – 90% with respect to the thresholds obtained with the standard trigger, ranging between ~ 20 and 100 keV. Low trigger thresholds open the way to Dark Matter searches and to improvements in the neutrinoless double beta decay analysis. Nevertheless, running the OT on CUORE data is demanding from the computational resources point of view. For this reason, the algorithm has been revised and adapted to cope with CUORE data. The work done to implement OT in CUORE and its performances will be discussed.

Published
2020

14. Searching for Neutrinoless Double-Beta Decay of130Te with CUORE

Author

A. De Biasi, M. Balata, N. Casali, P. Gorla, F. Ferroni, C. Tomei, F. Orio, Carlo Ligi, Alan R. Smith, Emanuele Ferri, Eugene E. Haller, M. Tenconi, B. S. Wang, B. X. Zhu, M. Faverzani, Massimiliano Clemenza, Davide Chiesa, O. Azzolini, M. Carrettoni, Marco Pallavicini, H. A. Farach, V. Pettinacci, A. Giuliani, G. Bari, X. Liu, Simone Capelli, R. W. Kadel, James R. Wilson, L. Cardani, N. Chott, G. Fernandes, N. Moggi, Oliviero Cremonesi, G. Pessina, Stuart Freedman, Ke Han, Reina H. Maruyama, Jeffrey W. Beeman, J. Goett, Yingqi Ma, T. Wise, R. J. Creswick, G. Keppel, D. R. Artusa, Monica Sisti, Y. L. Li, A. Bersani, V. Rampazzo, Marisa Pedretti, Samuele Sangiorgio, Stefano Nisi, H. Z. Huang, A. Nucciotti, G. Piperno, Elena Sala, Y. Mei, V. Palmieri, A. Dally, Yu G. Kolomensky, R. Hennings-Yeomans, Xi-Guang Cao, K. M. Heeger, Eric B. Norman, Ettore Fiorini, Silvio Morganti, L. Gironi, A. Woodcraft, T. I. Banks, C. Maiano, S. Pirro, T. Napolitano, G. Ventura, S. Trentalange, Lindley Winslow, F. T. Avignone, Nicholas Scielzo, Andrea Giachero, X. Z. Cai, F. Terranova, S. Di Domizio, M. Biassoni, C. Zarra, L. Wielgus, W. D. Tian, M. M. Deninno, M. Maino, B. K. Fujikawa, Claudio Gotti, L. Taffarello, C. Nones, J. L. Ouellet, K. Kazkaz, M. L. Di Vacri, H. W. Wang, C. Cosmelli, T. O'Donnell, C. Bucci, T. D. Gutierrez, M. Vignati, C. Rusconi, S. Copello, S. Zucchelli, C. Pira, Larissa M. Ejzak, F. Bellini, D. Orlandi, M. A. Franceschi, C. Brofferio, Alejandro E. Camacho, D. Q. Fang, L. Carbone, Ezio Previtali, L. Pattavina, L. Zanotti, L. Canonica, M. I. Martínez, M. Pavan, Ioan Dafinei, Vladimir Datskov, C. Rosenfeld, Artusa, D.R., Avignone, F.T., Azzolini, O., Balata, M., Banks, T.I., Bari, G., Beeman, J., Bellini, F., Bersani, A., Biassoni, M., Brofferio, C., Bucci, C., Cai, X.Z., Camacho, A., Canonica, L., Cao, X.G., Capelli, S., Carbone, L., Cardani, L., Carrettoni, M., Casali, N., Chiesa, D., Chott, N., Clemenza, M., Copello, S., Cosmelli, C., Cremonesi, O., Creswick, R.J., Dafinei, I., Dally, A., Datskov, V., De Biasi, A., Deninno, M.M., Di Domizio, S., Di Vacri, M.L., Ejzak, L., Fang, D.Q., Farach, H.A., Faverzani, M., Fernandes, G., Ferri, E., Ferroni, F., Fiorini, E., Franceschi, M.A., Freedman, S.J., Fujikawa, B.K., Giachero, A., Gironi, L., Giuliani, A., Goett, J., Gorla, P., Gotti, C., Gutierrez, T.D., Haller, E.E., Han, K., Heeger, K.M., Hennings-Yeomans, R., Huang, H.Z., Kadel, R., Kazkaz, K., Keppel, G., Kolomensky, Yu.G., Li, Y.L., Ligi, C., Liu, X., Ma, Y.G., Maiano, C., Maino, M., Martinez, M., Maruyama, R.H., Mei, Y., Moggi, N., Morganti, S., Napolitano, T., Nisi, S., Nones, C., Norman, E.B., Nucciotti, A., O'Donnell, T., Orio, F., Orlandi, D., Ouellet, J.L., Pallavicini, M., Palmieri, V., Pattavina, L., Pavan, M., Pedretti, M., Pessina, G., Pettinacci, V., Piperno, G., Pira, C., Pirro, S., Previtali, E., Rampazzo, V., Rosenfeld, C., Rusconi, C., Sala, E., Sangiorgio, S., Scielzo, N.D., Sisti, M., Smith, A.R., Taffarello, L., Tenconi, M., Terranova, F., Tian, W.D., Tomei, C., Trentalange, S., Ventura, G., Vignati, M., Wang, B.S., Wang, H.W., Wielgus, L., Wilson, J., Winslow, L.A., Wise, T., Woodcraft, A., Zanotti, L., Zarra, C., Zhu, B.X., Zucchelli, S., Artusa, D, Avignone, F, Azzolini, O, Balata, M, Banks, T, Bari, G, Beeman, J, Bellini, F, Bersani, A, Biassoni, M, Brofferio, C, Bucci, C, Cai, X, Camacho, A, Canonica, L, Cao, X, Capelli, S, Carbone, L, Cardani, L, Carrettoni, M, Casali, N, Chiesa, D, Chott, N, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, Dafinei, I, Dally, A, Datskov, V, De Biasi, A, Deninno, M, Di Domizio, S, Di Vacri, M, Ejzak, L, Fang, D, Farach, H, Faverzani, M, Fernandes, G, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Goett, J, Gorla, P, Gotti, C, Gutierrez, T, Haller, E, Han, K, Heeger, K, Hennings Yeomans, R, Huang, H, Kadel, R, Kazkaz, K, Keppel, G, Kolomensky, Y, Li, Y, Ligi, C, Liu, X, Ma, Y, Maiano, C, Maino, M, Martinez, M, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nisi, S, Nones, C, Norman, E, Nucciotti, A, O'Donnell, T, Orio, F, Orlandi, D, Ouellet, J, Pallavicini, M, Palmieri, V, Pattavina, L, Pavan, M, Pedretti, M, Pessina, G, Pettinacci, V, Piperno, G, Pira, C, Pirro, S, Previtali, E, Rampazzo, V, Rosenfeld, C, Rusconi, C, Sala, E, Sangiorgio, S, Scielzo, N, Sisti, M, Smith, A, Taffarello, L, Tenconi, M, Terranova, F, Tian, W, Tomei, C, Trentalange, S, Ventura, G, Vignati, M, Wang, B, Wang, H, Wielgus, L, Wilson, J, Winslow, L, Wise, T, Woodcraft, A, Zanotti, L, Zarra, C, Zhu, B, and Zucchelli, S

Subjects
Neutrinoless double-beta, Nuclear and High Energy Physics, Particle physics, Physics - Instrumentation and Detectors, FOS: Physical sciences, RESPONSE STABILIZATION, 7. Clean energy, VALIDATION, Nuclear physics, CUORICINO, CUORE, Double beta decay, DETECTORS, Nuclear Experiment (nucl-ex), Nuclear Experiment, Physics, BOLOMETERS, Half-life, Instrumentation and Detectors (physics.ins-det), Beta decay, lcsh:QC1-999, 3. Good health, MAJORANA, RARE EVENTS, High Energy Physics::Experiment, Nuclear and High Energy Physics. RADIOACTIVE CONTAMINATION, Neutrino, lcsh:Physics, Radioactive decay, Lepton
Abstract

Neutrinoless double-beta ($0\nu\beta\beta$) decay is a hypothesized lepton-number-violating process that offers the only known means of asserting the possible Majorana nature of neutrino mass. The Cryogenic Underground Observatory for Rare Events (CUORE) is an upcoming experiment designed to search for $0\nu\beta\beta$ decay of $^{130}$Te using an array of 988 TeO$_2$ crystal bolometers operated at 10 mK. The detector will contain 206 kg of $^{130}$Te and have an average energy resolution of 5 keV; the projected $0\nu\beta\beta$ decay half-life sensitivity after five years of live time is $1.6\times 10^{26}$ y at $1\sigma$ ($9.5\times10^{25}$ y at the 90% confidence level), which corresponds to an upper limit on the effective Majorana mass in the range 40--100 meV (50--130 meV). In this paper we review the experimental techniques used in CUORE as well as its current status and anticipated physics reach., Comment: 20 pages, 8 figures. Published in Advances in High Energy Physics, Volume 2015 (2015), Article ID 879871

Published
2015

15. CUORE crystal validation runs: Results on radioactive contamination and extrapolation to CUORE background

Author

S. Newman, M. Carrettoni, L. Pattavina, M. Balata, S. Kraft, Ke Han, Reina H. Maruyama, C. Arnaboldi, Stuart J. Freedman, C. Salvioni, R. J. Creswick, F. Alessandria, M. I. Martínez, D. Lenz, Eric B. Norman, E. Longo, X. Z. Cai, N. Xu, G. Bari, A. Woodcraft, I. C. Bandac, M. Pavan, Kareem Kazkaz, D. Schaeffer, E. Fiorini, A. Giachero, F. Orio, C. Bucci, T. D. Gutierrez, Massimiliano Clemenza, B. S. Wang, Alan R. Smith, D. Q. Fang, V. Palmieri, Giorgio Frossati, Simone Capelli, C. Rusconi, C. Brofferio, H. Z. Huang, Silvio Morganti, D. Orlandi, S. Zucchelli, F. Rimondi, B. X. Zhu, G. Terenziani, C. Nones, A. Dally, Cristián Martínez, A. Bryant, Jeffrey W. Beeman, Ioan Dafinei, Oliviero Cremonesi, M. Biassoni, C. A. Whitten, Raffaele Ardito, Yu. G. Kolomensky, L. Gironi, Y. L. Li, K. M. Heeger, E. Previtali, L. Canonica, Giulio Maier, Claudia Tomei, F. T. Avignone, X. Liu, T. I. Banks, L. Foggetta, S. Trentalange, M. M. Deninno, V. Rampazzo, A. Bersani, A. de Waard, Nicholas Scielzo, N. Moggi, F. Bellini, Marco Pallavicini, N. Chott, R. W. Kadel, E. Andreotti, S. Di Domizio, G. Pessina, C. Zarra, Laura Cardani, Samuele Sangiorgio, Stefano Nisi, A. Nucciotti, L. Zanotti, W. D. Tian, M. Vignati, Marisa Pedretti, Larissa M. Ejzak, A. De Biasi, G. Ventura, H. A. Farach, Claudio Gotti, T. Bloxham, T. Wise, C. Maiano, L. Taffarello, H. W. Wang, C. Cosmelli, Yu-Gang Ma, C. Rosenfeld, P. Gorla, F. Ferroni, Emanuele Ferri, Eugene E. Haller, R. Faccini, L. Kogler, Koichi Ichimura, E. Guardincerri, M. P. Decowski, J. L. Ouellet, L. Carbone, F. Stivanello, S. Pirro, G. Keppel, Monica Sisti, A. Giuliani, Alessandria, F, Andreotti, E, Ardito, R, Arnaboldi, C, Avignone, F, Balata, M, Bandac, I, Banks, T, Bari, G, Beeman, J, Bellini, F, Bersani, A, Biassoni, M, Bloxham, T, Brofferio, C, Bryant, A, Bucci, C, Cai, X, Canonica, L, Capelli, S, Carbone, L, Cardani, L, Carrettoni, M, Chott, N, Clemenza, M, Cosmelli, C, Cremonesi, O, Creswick, R, Dafinei, I, Dally, A, De Biasi, A, Decowski, M, Deninno, M, de Waard, A, Di Domizio, S, Ejzak, L, Faccini, R, Fang, D, Farach, H, Ferri, E, Ferroni, F, Fiorini, E, Foggetta, L, Freedman, S, Frossati, G, Giachero, A, Gironi, L, Giuliani, A, Gorla, P, Gotti, C, Guardincerri, E, Gutierrez, T, Haller, E, Han, K, Heeger, K, Huang, H, Ichimura, K, Kadel, R, Kazkaz, K, Keppel, G, Kogler, L, Kolomensky, Y, Kraft, S, Lenz, D, Li, Y, Liu, X, Longo, E, Ma, Y, Maiano, C, Maier, G, Martinez, C, Martinez, M, Maruyama, R, Moggi, N, Morganti, S, Newman, S, Nisi, S, Nones, C, Norman, E, Nucciotti, A, Orio, F, Orlandi, D, Ouellet, J, Pallavicini, M, Palmieri, V, Pattavina, L, Pavan, M, Pedretti, M, Pessina, G, Pirro, S, Previtali, E, Rampazzo, V, Rimondi, F, Rosenfeld, C, Rusconi, C, Salvioni, C, Sangiorgio, S, Schaeffer, D, Scielzo, N, Sisti, M, Smith, A, Stivanello, F, Taffarello, L, Terenziani, G, Tian, W, Tomei, C, Trentalange, S, Ventura, G, Vignati, M, Wang, B, Wang, H, Whitten, C, Wise, T, Woodcraft, A, Xu, N, Zanotti, L, Zarra, C, Zhu, B, Zucchelli, S, CSNSM PS2, Centre de Spectrométrie Nucléaire et de Spectrométrie de Masse (CSNSM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), IoP (FNWI), Gravitation and Astroparticle Physics Amsterdam, GRAPPA (ITFA, IoP, FNWI), Faculty of Science, Other Research IHEF (IoP, FNWI), F. Alessandria, E. Andreotti, R. Ardito, C. Arnaboldi, F.T. Avignone III, M. Balata, I. Bandac, T.I. Bank, G. Bari, J. Beeman, F. Bellini, A. Bersani, M. Biassoni, T. Bloxham, C. Brofferio, A. Bryant, C. Bucci, X.Z. Cai, L. Canonica, S. Capelli, L. Carbone, L. Cardani, M. Carrettoni, N. Chott, M. Clemenza, C. Cosmelli, O. Cremonesi, R.J. Creswick, I. Dafinei, A. Dally, A. De Biasi, M.P. Decowski, M.M. Deninno, A. de Waard, S. Di Domizio, L. Ejzak, R. Faccini, D.Q. Fang, H.A. Farach, E. Ferri, F. Ferroni, E. Fiorini, L. Foggetta, S.J. Freedman, G. Frossati, A. Giachero, L. Gironi, A. Giuliani, P. Gorla, C. Gotti, E. Guardincerri, T.D. Gutierrez, E.E. Haller, K. Han, K.M. Heeger, H.Z. Huang, K. Ichimura, R. Kadel, K. Kazkaz, G. Keppel, L. Kogler, Yu.G. Kolomensky, S. Kraft, D. Lenz, Y.L. Li, X. Liu, E. Longo, Y.G. Ma, C. Maiano, G. Maier, C. Martinez, M. Martinez, R.H. Maruyama, N. Moggi, S. Morganti, S. Newman, S. Nisi, C. None, E.B. Norman, A. Nucciotti, F. Orio, D. Orlandi, J.L. Ouellet, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, M. Pedretti, G. Pessina, S. Pirro, E. Previtali, V. Rampazzo, F. Rimondi, C. Rosenfeld, C. Rusconi, C. Salvioni, S. Sangiorgio, D. Schaeffer, N.D. Scielzo, M. Sisti, A.R. Smith, F. Stivanello, L. Taffarello, G. Terenziani, W.D. Tian, C. Tomei, S. Trentalange, G. Ventura, M. Vignati, B.S. Wang, H.W. Wang, C.A. Whitten Jr., T. Wise, A. Woodcraft, N. Xu, L. Zanotti, C. Zarra, B.X. Zhu, and S. Zucchelli

Subjects
Extrapolation, FOS: Physical sciences, 01 natural sciences, Nuclear physics, CUORE, ESPERIMENTO CUORE, 0103 physical sciences, Radioactive contamination, radioactive contamination, tellurium dioxide, double beta decay, Quality monitoring, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Nuclide, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Physics, 010308 nuclear & particles physics, Tellurium dioxide, Astronomy and Astrophysics, Radioactive contamination DETECTORS, Double beta decay, Chinese academy of sciences, [PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci], LABORATORI NAZIONALI DEL GRAN SASSO, FIS/04 - FISICA NUCLEARE E SUBNUCLEARE
Abstract

The CUORE Crystal Validation Runs (CCVRs) have been carried out since the end of 2008 at the Gran Sasso National Laboratories, in order to test the performances and the radiopurity of the TeO$_2$ crystals produced at SICCAS (Shanghai Institute of Ceramics, Chinese Academy of Sciences) for the CUORE experiment. In this work the results of the first 5 validation runs are presented. Results have been obtained for bulk contaminations and surface contaminations from several nuclides. An extrapolation to the CUORE background has been performed., 11 pages, 8 figures

Published
2012

16. Readout Electronics for the Kinetic Inductance Detectors of CALDER

Author

C. Cosmelli, Angelo Cruciani, C. Tomei, Marco Castellano, L. Minutolo, N. Casali, A. D'Addabbo, F. Bellini, Miriam Lucio Martinez, S. Di Domizio, Laura Cardani, M. Vignati, and I. Colantoni

Subjects
Superconductivity, Physics, Physics::Instrumentation and Detectors, business.industry, Detector, Cryogenics, LC circuit, Kinetic inductance, Inductance, Resonator, Condensed Matter::Superconductivity, Optoelectronics, Cooper pair, business
Abstract

When we apply an AC current to a superconductor, the Cooper pairs oscillate and acquire kinetic inductance, that can be measured by inserting the superconductor in a LC circuit with high merit factor. Interactions in the superconductor can break the Cooper pairs,causing sizable variations in the kinetic inductance and, thus, the response of the LC circuit. This concept is at the basis of Kinetic Inductance Detectors (KIDs). The CALDER project aims to develope high sensitivity, cryogenic light detectors using KIDs in combination with a silicon absorber to cover, via phonon mediation, an area of several cm2 [1]. This contribution focuses on the development of a low-noise, digital and analogical,electronics for the sensor's readout and on the design and testing of a new geometry for the superconductive resonator to improve detector sensitivity.

Published
2017

17. Results from CUORE and CUORE-0

Author

C. Rosenfeld, P. Gorla, F. Ferroni, C. Tomei, Emanuele Ferri, H. W. Wang, C. J. Davis, A. Camacho, Carlo Ligi, S. J. Freedman, M. M. Deninno, H. Z. Huang, N. D. Scielzo, E. Fiorini, N. Moggi, Massimiliano Clemenza, Lucia Canonica, Yu. G. Kolomensky, Luigi Cappelli, C. Pagliarone, S. S. Nagorny, Monica Sisti, F. Bellini, Samuele Sangiorgio, R. Hennings-Yeomans, S. Pozzi, Oliviero Cremonesi, S. Zimmermann, A. Nucciotti, B. Schmidt, A. Caminata, C. Alduino, M. Faverzani, T. Wise, R. J. Creswick, K. Alfonso, C. Bucci, Miriam Lucio Martinez, Marco Pallavicini, L. Pattavina, A. Woodcraft, Lindley Winslow, Jonathan Ouellet, B. Welliver, M. L. Di Vacri, G. Pessina, G. Bari, L. Taffarello, C. Brofferio, P. J. Mosteiro, Guimin Zhang, L. Gironi, F. T. Avignone, Lorenzo Cassina, V. Singh, S. L. Wagaarachchi, Giovanni Benato, C. Pira, N. Casali, C. Cosmelli, C. Nones, V. Palmieri, T. D. Gutierrez, E. Previtali, F. Terranova, C. Rusconi, Eric B. Norman, A. D'Addabbo, M. Sakai, T. Napolitano, Simone Capelli, N. Chott, L. Marini, V. Novati, D. D'Aguanno, M. Biassoni, S. Copello, S. Morganti, Paolo Carniti, Ke Han, A. Branca, Reina H. Maruyama, Y. Mei, Stefano Dell'Oro, Stefano Zucchelli, Xi-Guang Cao, K. M. Heeger, J. Schmidt, T. O'Donnell, Yu-Gang Ma, G. Keppel, D. R. Artusa, M. Pavan, Massimiliano Nastasi, A. Giuliani, A. Bersani, I. Dafinei, Davide Chiesa, K. E. Lim, Jeremy S. Cushman, L. Zanotti, A. Leder, A. Drobizhev, D. Santone, J. S. Wilson, B. S. Wang, O. Azzolini, M. A. Franceschi, C. Gotti, A. Giachero, D. Q. Fang, L. Gladstone, S. Pirro, S. Di Domizio, Laura Cardani, B. K. Fujikawa, M. Vignati, Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Département de Physique des Particules (ex SPP) (DPhP), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Département de Physique des Particules (ex SPP) (DPP), Moggi, N, Alduino, C, Alfonso, K, Artusa, D, Avignone, F, Azzolini, O, Bari, G, Bellini, F, Benato, G, Bersani, A, Biassoni, M, Branca, A, Brofferio, C, Bucci, C, Camacho, A, Caminata, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Cardani, L, Carniti, P, Casali, N, Cassina, L, Chiesa, D, Chott, N, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, Cushman, J, D'Addabbo, A, D'Aguanno, D, Dafinei, I, Davis, C, Dell'Oro, S, Deninno, M, Di Domizio, S, Di Vacri, M, Drobizhev, A, Fang, D, Faverzani, M, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gladstone, L, Gorla, P, Gotti, C, Gutierrez, T, Han, K, Heeger, K, Hennings-Yeomans, R, Huang, H, Keppel, G, Kolomensky, Y, Leder, A, Ligi, C, Lim, K, Ma, Y, Marini, L, Martinez, M, Maruyama, R, Mei, Y, Morganti, S, Mosteiro, P, Nagorny, S, Napolitano, T, Nastasi, M, Nones, C, Norman, E, Novati, V, Nucciotti, A, O'Donnell, T, Ouellet, J, Pagliarone, C, Pallavicini, M, Palmieri, V, Pattavina, L, Pavan, M, Pessina, G, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Rosenfeld, C, Rusconi, C, Sakai, M, Sangiorgio, S, Santone, D, Schmidt, B, Schmidt, J, Scielzo, N, Singh, V, Sisti, M, Taffarello, L, Terranova, F, Tomei, C, Vignati, M, Wagaarachchi, S, Wang, B, Wang, H, Welliver, B, Wilson, J, Winslow, L, Wise, T, Woodcraft, A, Zanotti, L, Zhang, G, Zimmermann, S, Zucchelli, S, Moggi, N., Alduino, C., Alfonso, K., Artusa, D. R., Avignone, F. T., Azzolini, O., Bari, G., Bellini, F., Benato, G., Bersani, A., Biassoni, M., Branca, A., Brofferio, C., Bucci, C., A., Camacho, Caminata, A., Canonica, L., Cao, X. G., Capelli, S., Cappelli, L., Cardani, L., Carniti, P., Casali, N., Cassina, L., Chiesa, D., Chott, N., Clemenza, M., Copello, S., Cosmelli, C., Cremonesi, O., Creswick, R. J., Cushman, J. S., D'Addabbo, A., D'Aguanno, D., Dafinei, I., Davis, C. J., Dell'Oro, S., Deninno, M. M., Di Domizio, S., Di Vacri, M. L., Drobizhev, A., Fang, D. Q., Faverzani, M., Ferri, E., Ferroni, F., Fiorini, E., Franceschi, M. A., Freedman, S. J., Fujikawa, B. K., Giachero, A., Gironi, L., Giuliani, A., Gladstone, L., Gorla, P., Gotti, C., Gutierrez, T. D., Han, K., Heeger, K. M., Hennings-Yeomans, R., Huang, H. Z., Keppel, G., Kolomensky, Yu. G., Leder, A., Ligi, C., Lim, K. E., Ma, Y. G., Marini, L., Martinez, M., Maruyama, R. H., Mei, Y., Morganti, S., Mosteiro, P. J., Nagorny, S. S., Napolitano, T., Nastasi, M., Nones, C., Norman, E. B., Novati, V., Nucciotti, A., O'Donnell, T., Ouellet, J. L., Pagliarone, C. E., Pallavicini, M., Palmieri, V., Pattavina, L., Pavan, M., Pessina, G., Pira, C., Pirro, S., Pozzi, S., Previtali, E., Rosenfeld, C., Rusconi, C., Sakai, M., Sangiorgio, S., Santone, D., Schmidt, B., Schmidt, J., Scielzo, N. D., Singh, V., Sisti, M., Taffarello, L., Terranova, F., Tomei, C., Vignati, M., Wagaarachchi, S. L., Wang, B. S., Wang, H. W., Welliver, B., Wilson, J., Winslow, L. A., Wise, T., Woodcraft, A., Zanotti, L., Zhang, G. Q., S., Zimmermann, Zucchelli, S., and Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)

Subjects
Cryostat, Particle physics, detector: performance, Physics::Instrumentation and Detectors, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, 7. Clean energy, tellurium: oxygen, law.invention, Physics and Astronomy (all), CUORE, background: low, Contamination, double-beta decay: (0neutrino), bolometer, Observatory, law, Double beta decay, Validation, 0103 physical sciences, Neutrino Physics, 010306 general physics, Double Beta Decay, Particle Physics, Physics, Neutrino Physics, Double Beta Decay, Particle Physics, 010308 nuclear & particles physics, Bolometer, Detector, observatory, cryogenics, High Energy Physics::Experiment, tellurium: nuclide, experimental results
Abstract

International audience; The Cryogenic Underground Observatory for Rare Events (CUORE) is the first bolometric experiment searching for neutrinoless double beta decay that has been able to reach the 1-ton scale. The detector consists of an array of 988 TeO2 crystals arranged in a cylindrical compact structure of 19 towers. The construction of the experiment and the installation of all towers in the cryostat was completed in August 2016: the experiment is now in data taking phase. In this talk, beyond updating the physics results from CUORE-0, we will discuss the achievements and technical challenges of the CUORE construction phase, with particular emphasis on the background reduction strategy, the performance of the detector during pre-operation and the projected first results from the full detector run.

Published
2017

18. Exploring the neutrinoless double beta decay in the inverted neutrino hierarchy with bolometric detectors

Author

Oliviero Cremonesi, Carlo Ligi, J. Goett, T. I. Banks, M. Balata, M. Carrettoni, S. Trentalange, J. W. Beeman, Nicholas Scielzo, Ettore Fiorini, S. Zucchelli, Davide Chiesa, Massimiliano Clemenza, Marisa Pedretti, N. Casali, Andrea Giachero, N. Chott, P. Gorla, F. Ferroni, L. Wielgus, W. D. Tian, G. Piperno, Emanuele Ferri, Eugene E. Haller, L. Canonica, Xiangyu Cao, M. Pavan, Alan R. Smith, Ke Han, Reina H. Maruyama, Stuart J. Freedman, N. Moggi, Jonathan Ouellet, G. Bari, B. S. Wang, M. L. Di Vacri, L. Carbone, L. Pattavina, L. Taffarello, C. Pira, L. Zanotti, A. Bersani, T. Wise, A. De Biasi, Silvia Capelli, F. Orio, L. Gironi, Elena Sala, Y. Mei, X. Liu, F. T. Avignone, Claudio Gotti, M. Maino, V. Rampazzo, Eric B. Norman, Lindley Winslow, Yu G. Kolomensky, Ezio Previtali, H. Z. Huang, R. Hennings-Yeomans, G. Ventura, O. Azzolini, S. Pirro, Larissa M. Ejzak, B. X. Zhu, C. Cosmelli, I. Dafinei, M. Biassoni, S. Di Domizio, C. Zarra, K. M. Heeger, A. Woodcraft, C. Nones, T. O'Donnell, B. K. Fujikawa, M. I. Martínez, M. Tenconi, K. Kazkaz, M. M. Deninno, V. Palmieri, S. Morganti, R. W. Kadel, Francesca Bellini, S. Nisi, James R. Wilson, R. J. Creswick, T. D. Gutierrez, F. Terranova, M. Vignati, Yong-Ping Li, C. Rusconi, M. Faverzani, H. A. Farach, G. Keppel, D. R. Artusa, T. Napolitano, V. Pettinacci, A. Giuliani, C. Maiano, G. Fernandes, Monica Sisti, Hongwei Wang, L. Cardani, Vladimir Datskov, A. Dally, Yu-Gang Ma, C. Bucci, Deqing Fang, X. Z. Cai, Marco Pallavicini, Claudia Tomei, G. Pessina, C. Rosenfeld, C. Brofferio, Alejandro E. Camacho, Samuele Sangiorgio, A. Nucciotti, D. Orlandi, M. A. Franceschi, Artusa, D, Avignone, F, Azzolini, O, Balata, M, Banks, T, Bari, G, Beeman, J, Bellini, F, Bersani, A, Biassoni, M, Brofferio, C, Bucci, C, Cai, X, Camacho, A, Canonica, L, Cao, X, Capelli, S, Carbone, L, Cardani, L, Carrettoni, M, Casali, N, Chiesa, D, Chott, N, Clemenza, M, Cosmelli, C, Cremonesi, O, Creswick, R, Dafinei, I, Dally, A, Datskov, V, De Biasi, A, Deninno, M, Di Domizio, S, Di Vacri, M, Ejzak, L, Fang, D, Farach, H, Faverzani, M, Fernandes, G, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Goett, J, Gorla, P, Gotti, C, Gutierrez, T, Haller, E, Han, K, Heeger, K, Hennings Yeomans, R, Huang, H, Kadel, R, Kazkaz, K, Keppel, G, Kolomensky, Y, Li, Y, Ligi, C, Liu, X, Ma, Y, Maiano, C, Maino, M, Martinez, M, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Nisi, S, Nones, C, Norman, E, Nucciotti, A, O’Donnell, T, Orio, F, Orlandi, D, Ouellet, J, Pallavicini, M, Palmieri, V, Pattavina, L, Pavan, M, Pedretti, M, Pessina, G, Pettinacci, V, Piperno, G, Pira, C, Pirro, S, Previtali, E, Rampazzo, V, Rosenfeld, C, Rusconi, C, Sala, E, Sangiorgio, S, Scielzo, N, Sisti, M, Smith, A, Taffarello, L, Tenconi, M, Terranova, F, Tian, W, Tomei, C, Trentalange, S, Ventura, G, Vignati, M, Wang, B, Wang, H, Wielgus, L, Wilson, J, Winslow, L, Wise, T, Woodcraft, A, Zanotti, L, Zarra, C, Zhu, B, Zucchelli, S, D. R. Artusa, F. T. Avignone, O. Azzolini, M. Balata, T. I. Bank, G. Bari, J. Beeman, F. Bellini, A. Bersani, M. Biassoni, C. Brofferio, C. Bucci, X. Z. Cai, A. Camacho, L. Canonica, X. G. Cao, S. Capelli, L. Carbone, L. Cardani, M. Carrettoni, N. Casali, D. Chiesa, N. Chott, M. Clemenza, C. Cosmelli, O. Cremonesi, R. J. Creswick, I. Dafinei, A. Dally, V. Datskov, A. De Biasi, M. M. Deninno, S. Di Domizio, M. L. Di Vacri, L. Ejzak, D. Q. Fang, H. A. Farach, M. Faverzani, G. Fernande, E. Ferri, F. Ferroni, E. Fiorini, M. A. Franceschi, S. J. Freedman, B. K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, J. Goett, P. Gorla, C. Gotti, T. D. Gutierrez, E. E. Haller, K. Han, K. M. Heeger, R. Hennings-Yeoman, H. Z. Huang, R. Kadel, K. Kazkaz, G. Keppel, Yu. G. Kolomensky, Y. L. Li, C. Ligi, X. Liu, Y. G. Ma, C. Maiano, M. Maino, M. Martinez, R. H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, S. Nisi, C. None, E. B. Norman, A. Nucciotti, T. O’Donnell, F. Orio, D. Orlandi, J. L. Ouellet, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, M. Pedretti, G. Pessina, V. Pettinacci, G. Piperno, C. Pira, S. Pirro, E. Previtali, V. Rampazzo, C. Rosenfeld, C. Rusconi, E. Sala, S. Sangiorgio, N. D. Scielzo, M. Sisti, A. R. Smith, L. Taffarello, M. Tenconi, F. Terranova, W. D. Tian, C. Tomei, S. Trentalange, G. Ventura, M. Vignati, B. S. Wang, H. W. Wang, L. Wielgu, J. Wilson, L. A. Winslow, T. Wise, A. Woodcraft, L. Zanotti, C. Zarra, B. X. Zhu, and S. Zucchelli

Subjects
Particle physics, J.2, Physics - Instrumentation and Detectors, Experimental Physics, Physics and Astronomy (miscellaneous), Physics beyond the Standard Model, FOS: Physical sciences, 01 natural sciences, law.invention, High Energy Physics - Experiment, Nuclear physics, High Energy Physics - Experiment (hep-ex), CUORE, law, Double beta decay, 0103 physical sciences, Physics and Astronomy, Beta (velocity), neutrinole, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Engineering (miscellaneous), Physics, 010308 nuclear & particles physics, Bolometer, bolometry, Instrumentation and Detectors (physics.ins-det), Beta decay, MAJORANA, DOUBLE-BETA DECAY, Neutrino
Abstract

Neutrinoless double beta decay (0nubb) is one of the most sensitive probes for physics beyond the Standard Model, providing unique information on the nature of neutrinos. In this paper we review the status and outlook for bolometric 0nubb decay searches. We summarize recent advances in background suppression demonstrated using bolometers with simultaneous readout of heat and light signals. We simulate several configurations of a future CUORE-like bolometer array which would utilize these improvements and present the sensitivity reach of a hypothetical next-generation bolometric 0nubb experiment. We demonstrate that a bolometric experiment with the isotope mass of about 1 ton is capable of reaching the sensitivity to the effective Majorana neutrino mass (|mee|) of order 10-20 meV, thus completely exploring the so-called inverted neutrino mass hierarchy region. We highlight the main challenges and identify priorities for an R&D program addressing them., 22 pages, 15 figures, submitted to EPJC

Published
2014

19. Analysis techniques for the evaluation of the neutrinoless double-βdecay lifetime inTe130with the CUORE-0 detector

Author

L. Marini, N. Casali, C. Bucci, T. D. Gutierrez, M. Tenconi, M. Pavan, D. Santone, K. Alfonso, R. Hennings-Yeomans, A. Caminata, Marco Pallavicini, S. Zucchelli, L. Pattavina, Ioan Dafinei, Oliviero Cremonesi, Alan R. Smith, G. Fernandes, G. Pessina, M. Faverzani, L. Zanotti, Massimiliano Clemenza, Monica Sisti, C. Rosenfeld, L. Gladstone, A. Bersani, L. Cardani, Jonathan Ouellet, E. Previtali, P. Gorla, F. Ferroni, C. Tomei, L. Carbone, A. Woodcraft, C. Pagliarone, A. Giuliani, G. Bari, Stuart Freedman, R. J. Creswick, V. Palmieri, T. I. Banks, Eugene E. Haller, C. Brofferio, P. J. Mosteiro, S. L. Wagaarachchi, M. I. Martínez, S. Pozzi, L. Gironi, Eric B. Norman, F. T. Avignone, A. Dally, S. Zimmermann, Evelyn Ferri, James R. Wilson, Silvio Morganti, Jeremy S. Cushman, C. J. Davis, S. Di Domizio, Nicholas Scielzo, F. Terranova, S. Trentalange, D. R. Artusa, K. P. Hickerson, B. K. Fujikawa, G. Ventura, N. Moggi, G. Piperno, Liu Xt, M. M. Deninno, C. Gotti, M. Biassoni, T. Wise, A. Giachero, Lucia Canonica, Yinina Ma, M. Vignati, D. Q. Fang, N. Chott, Samuele Sangiorgio, A. Nucciotti, B. X. Zhu, F. Bellini, Davide Chiesa, K. E. Lim, Lorenzo Cassina, L. Taffarello, Ke Han, C. Nones, C. Alduino, S. Pirro, Jeffrey W. Beeman, Reina H. Maruyama, H. W. Wang, A. Drobizhev, T. O'Donnell, Elena Sala, Guimin Zhang, Y. Mei, Stefano Dell'Oro, F. Orio, Vasundhara Singh, Xi-Guang Cao, K. M. Heeger, Luigi Cappelli, H. Z. Huang, B. S. Wang, O. Azzolini, Yu G. Kolomensky, C. Cosmelli, Simone Capelli, R. W. Kadel, E. Fiorini, M. L. Di Vacri, S. Copello, Paolo Carniti, G. Keppel, Lindley Winslow, M. Maino, E. V. Hansen, C. Rusconi, and V. Pettinacci

Subjects
Physics, 010308 nuclear & particles physics, Detector, Bremsstrahlung, 01 natural sciences, Beta decay, Upper and lower bounds, Nuclear physics, MAJORANA, CUORE, 0103 physical sciences, Beta (velocity), Neutrino, 010306 general physics
Abstract

We describe in detail the methods used to obtain the lower bound on the lifetime of neutrinoless double-beta (0 nu beta beta) decay in Te-130 and the associated limit on the effective Majorana mass of the neutrino using the CUORE-0 detector. CUORE-0 is a bolometric detector array located at the Laboratori Nazionali del Gran Sasso that was designed to validate the background reduction techniques developed for CUORE, a next-generation experiment scheduled to come online in 2016. CUORE-0 is also a competitive 0 nu beta beta decay search in its own right and functions as a platform to further develop the analysis tools and procedures to be used in CUORE. These include data collection, event selection and processing, as well as an evaluation of signal efficiency. In particular, we describe the amplitude evaluation, thermal gain stabilization, energy calibration methods, and the analysis event selection used to create our final 0 nu beta beta search spectrum. We define our high level analysis procedures, with emphasis on the new insights gained and challenges encountered. We outline in detail our fitting methods near the hypothesized 0 nu beta beta decay peak and catalog the main sources of systematic uncertainty. Finally, we derive the 0 nu beta beta decay half-life limits previously reported for CUORE-0, T-1/2(0 nu) > 2.7 x 10(24) yr, and in combination with the Cuoricino limit, T-1/2(0 nu) > 4.0 x 10(24) yr.

Published
2016

20. CUORE-0 detector: design, construction and operation

Author

N. Casali, R. Mazza, S. Zimmermann, C. Rosenfeld, G. Ventura, M. I. Martínez, P. Gorla, F. Ferroni, C. Tomei, Emanuele Ferri, Eugene E. Haller, G. Ceruti, A. Leder, Alan R. Smith, S. Copello, L. Ioannucci, Paolo Carniti, M. Iannone, David Miller, Massimiliano Nastasi, S. L. Wagaarachchi, R. Gaigher, M. Maino, H. W. Wang, C. Cosmelli, T. O'Donnell, Yu-Gang Ma, C. Nones, D. Conventi, A. Giuliani, S. Trentalange, Simone Capelli, R. W. Kadel, B. X. Zhu, Massimiliano Clemenza, S. Di Domizio, G. Fernandes, L. Tatananni, G. Piperno, Ettore Fiorini, R. Michinelli, Davide Chiesa, Claudio Gotti, C. Zarra, K. E. Lim, S. Zucchelli, N. Moggi, F. Orio, Vasundhara Singh, B. K. Fujikawa, James R. Wilson, N. Chott, Samuele Sangiorgio, Stefano Nisi, Stefano Pozzi, A. Nucciotti, C. J. Davis, Oliviero Cremonesi, G. Keppel, D. R. Artusa, Monica Sisti, C. Brofferio, C. Alduino, P. J. Mosteiro, K. Alfonso, F. Bragazzi, G. Erme, M. L. Di Vacri, T. I. Banks, G. Bari, B. S. Wang, Y. u. G. Kolomensky, D. Santone, Ioan Dafinei, L. Carbone, A. Bersani, Marco Pallavicini, O. Azzolini, Lindley Winslow, M. Vignati, M. Cariello, M. Balata, H. Z. Huang, L. Taffarello, G. Pessina, Stefano Dell'Oro, M. Pavan, L. Zanotti, E. V. Hansen, X. Liu, Luigi Cappelli, R. Pedrotta, Nicholas Scielzo, A. Caminata, J. Wallig, Ezio Previtali, Lorenzo Cassina, A. Pelosi, Jeremy S. Cushman, C. Bulfon, F. Stivanello, C. Rusconi, M. Faverzani, V. Pettinacci, R. Cereseto, L. Pattavina, L. Cardani, G. Pancaldi, D. Biare, M. Perego, L. Canonica, L. Marini, Kevin Hickerson, A. Buccheri, A. Giachero, M. Capodiferro, D. Q. Fang, V. Palmieri, Eric B. Norman, J. W. Beeman, S. Meijer, Silvio Morganti, M. Guetti, Guoqiang Zhang, M. Biassoni, J. L. Ouellet, Ke Han, Reina H. Maruyama, A. Drobizhev, Stuart J. Freedman, C. Pagliarone, D. Orlandi, T. Wise, A. Chiarini, S. Pirro, F. Terranova, Elena Sala, Y. Mei, M. Tessaro, L. Gladstone, R. Hennings-Yeomans, Xi-Guang Cao, R. J. Creswick, K. M. Heeger, M. M. Deninno, F. Bellini, M. Tenconi, C. Bucci, T. D. Gutierrez, L. DiPaolo, L. Gironi, F. T. Avignone, A. D'Addabbo, Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Département de Physique des Particules (ex SPP) (DPhP), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, CUORE, Alduino, C, Alfonso, K, Artusa, D, Iii, F, Azzolini, O, Balata, M, Banks, T, Bari, G, Beeman, J, Bellini, F, Bersani, A, Biare, D, Biassoni, M, Bragazzi, F, Brofferio, C, Buccheri, A, Bucci, C, Bulfon, C, Caminata, A, Canonica, L, Cao, X, Capelli, S, Capodiferro, M, Cappelli, L, Carbone, L, Cardani, L, Cariello, M, Carniti, P, Casali, N, Cassina, L, Cereseto, R, Ceruti, G, Chiarini, A, Chiesa, D, Chott, N, Clemenza, M, Conventi, D, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, Cushman, J, D'Addabbo, A, Dafinei, I, Davis, C, Dell'Oro, S, Deninno, M, Domizio, S, Vacri, M, Dipaolo, L, Drobizhev, A, Erme, G, Fang, D, Faverzani, M, Fernandes, G, Ferri, E, Ferroni, F, Fiorini, E, Freedman, S, Fujikawa, B, Gaigher, R, Giachero, A, Gironi, L, Giuliani, A, Gladstone, L, Gorla, P, Gotti, C, Guetti, M, Gutierrez, T, Haller, E, Han, K, Hansen, E, Heeger, K, Hennings Yeomans, R, Hickerson, K, Huang, H, Iannone, M, Ioannucci, L, Kadel, R, Keppel, G, Kolomensky, Y, Leder, A, Lim, K, Liu, X, Ma, Y, Maino, M, Marini, L, Martinez, M, Maruyama, R, Mazza, R, Mei, Y, Meijer, S, Michinelli, R, Miller, D, Moggi, N, Morganti, S, Mosteiro, P, Nastasi, M, Nisi, S, Nones, C, Norman, E, Nucciotti, A, O'Donnell, T, Orio, F, Orlandi, D, Ouellet, J, Pagliarone, C, Pallavicini, M, Palmieri, V, Pancaldi, G, Pattavina, L, Pavan, M, Pedrotta, R, Pelosi, A, Perego, M, Pessina, G, Pettinacci, V, Piperno, G, Pirro, S, Pozzi, S, Previtali, E, Rosenfeld, C, Rusconi, C, Sala, E, Sangiorgio, S, Santone, D, Scielzo, N, Singh, V, Sisti, M, Smith, A, Stivanello, F, Taffarello, L, Tatananni, L, Tenconi, M, Terranova, F, Tessaro, M, Tomei, C, Trentalange, S, Ventura, G, Vignati, M, Wagaarachchi, S, Wallig, J, Wang, B, Wang, H, Wilson, J, Winslow, L, Wise, T, Zanotti, L, Zarra, C, Zhang, G, Zhu, B, Zimmermann, S, Zucchelli, S, Cuore, Collaboration, Alduino, C., Alfonso, K., Artusa, D. R., Avignone III, F. T., Azzolini, O., Balata, M., Banks, T. I., Bari, G., Beeman, J. W., Bellini, F., Bersani, A., Biare, D., Biassoni, M., Bragazzi, F., Brofferio, C., Buccheri, A., Bucci, C., Bulfon, C., Caminata, A., Canonica, L., Cao, X. G., Capelli, S., Capodiferro, M., Cappelli, L., Carbone, L., Cardani, L., Cariello, M., Carniti, P., Casali, N., Cassina, L., Cereseto, R., Ceruti, G., Chiarini, A., Chiesa, D., Chott, N., Clemenza, M., Conventi, D., Copello, S., Cosmelli, C., Cremonesi, O., Creswick, R. J., Cushman, J. S., Dafinei, I., Davis, C. J., Dell'Oro, S., Deninno, M. M., Di Domizio, S., Di Vacri, M. L., Dipaolo, L., Drobizhev, A., Erme, G., Fang, D. Q., Faverzani, M., Fernandes, G., Ferri, E., Ferroni, F., Fiorini, E., Freedman, S. J., Fujikawa, B. K., Gaigher, R., Giachero, A., Gironi, L., Giuliani, A., Gladstone, L., Gorla, P., Gotti, C., Guetti, M., Gutierrez, T. D., Haller, E. E., Han, K., Hansen, E., Heeger, K. M., Hennings-Yeomans, R., Hickerson, K. P., Huang, H. Z., Iannone, M., Ioannucci, L., Kadel, R., Keppel, G., Kolomensky, Yu. G., Leder, A., Lim, K. E., Liu, X., Ma, Y. G., Maino, M., Marini, L., Martinez, M., Maruyama, R. H., Mazza, R., Mei, Y., Meijer, S., Michinelli, R., Miller, D., Moggi, N., Morganti, S., Mosteiro, P. J., Nastasi, M., Nisi, S., Nones, C., Norman, E. B., Nucciotti, A., O'Donnell, T., Orio, F., Orlandi, D., Ouellet, J. L., Pagliarone, C. E., Pallavicini, M., Palmieri, V., Pancaldi, G., Pattavina, L., Pavan, M., Pedrotta, R., Pelosi, A., Perego, M., Pessina, G., Pettinacci, V., Piperno, G., Pirro, S., Pozzi, S., Previtali, E., Rosenfeld, C., Rusconi, C., Sala, E., Sangiorgio, S., Santone, D., Scielzo, N. D., Singh, V., Sisti, M., Smith, A. R., Stivanello, F., Taffarello, L., Tatananni, L., Tenconi, M., Terranova, F., Tessaro, M., Tomei, C., Trentalange, S., Ventura, G., Vignati, M., Wagaarachchi, S. L., Wallig, J., Wang, B. S., Wang, H. W., Wilson, J., Winslow, L. A., Wise, T., Zanotti, L., Zarra, C., Zhang, G. Q., Zhu, B. X., Zimmermann, S., and Zucchelli, S.

Subjects
J.2, Physics - Instrumentation and Detectors, Cryogenics, Cryogenic, FOS: Physical sciences, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], CUORE Experiment, 01 natural sciences, tellurium: oxygen, Calorimeters, Double-beta decay detectors, Instrumentation, Mathematical Physics, CUORE, bolometer, 0103 physical sciences, Neutrino Physics, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Double Beta Decay (0 Neutrino), Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, detector: design, Physics, Cryogenic Engineering, Calorimeter, 010308 nuclear & particles physics, Instrumentation and Detectors (physics.ins-det), Bolometers, Cryostat, Double-beta decay detector, tellurium: nuclide, Physics - Instrumentation and Detector, Bolometers, Cryogenic Engineering, Double Beta Decay (0 Neutrino), CUORE Experiment, Neutrino Physics, Cryostat, Humanities, Tellurium compounds
Abstract

The CUORE experiment will search for neutrinoless double-beta decay of $^{130}$Te with an array of 988 TeO$_2$ bolometers arranged in 19 towers. CUORE-0, the first tower assembled according to the CUORE procedures, was built and commissioned at Laboratori Nazionali del Gran Sasso, and took data from March 2013 to March 2015. In this paper we describe the design, construction and operation of the CUORE-0 experiment, with an emphasis on the improvements made over a predecessor experiment, Cuoricino. In particular, we demonstrate with CUORE-0 data that the design goals of CUORE are within reach., Comment: 39 pages, 26 figures

Published
2016
Full Text
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21. Validation of techniques to mitigate copper surface contamination in CUORE

Author

F. Orio, L. Taffarello, M. Carrettoni, B. S. Wang, Kareem Kazkaz, O. Azzolini, Ke Han, Reina H. Maruyama, C. Rosenfeld, Stuart J. Freedman, A. Woodcraft, H. A. Farach, P. Gorla, A. Giuliani, F. Ferroni, V. Palmieri, Emanuele Ferri, Eugene E. Haller, M. M. Deninno, D. Orlandi, Y. L. Li, Ettore Fiorini, Eric B. Norman, A. Bersani, Massimiliano Clemenza, M. A. Franceschi, L. Canonica, Silvio Morganti, T. Napolitano, L. Kogler, N. Moggi, N. Chott, A. Giachero, G. Bari, Larissa M. Ejzak, M. Maino, Samuele Sangiorgio, Stefano Nisi, F. Bellini, W. D. Tian, H. W. Wang, C. Cosmelli, M. Biassoni, F. Stivanello, L. Zanotti, Y. Mei, Deqing Fang, A. Nucciotti, Claudio Gotti, X. Z. Cai, Marisa Pedretti, Simone Capelli, R. W. Kadel, C. Bucci, T. D. Gutierrez, T. Bloxham, M. L. Di Vacri, Raffaele Ardito, C. Brofferio, R. J. Creswick, S. Pirro, Oliviero Cremonesi, C. Maiano, K. M. Heeger, A. Goodsell, J. Goett, L. Carbone, Ezio Previtali, Marco Pallavicini, L. Gironi, F. T. Avignone, G. Pessina, G. Ventura, M. Balata, H. Z. Huang, Yu. G. Kolomensky, Franco Rimondi, S. Zucchelli, Nicholas Scielzo, J. L. Ouellet, R. Faccini, N. Casali, C. Nones, E. Guardincerri, X. Liu, Ioan Dafinei, Jeffrey W. Beeman, S. Newman, V. Rampazzo, L. Pattavina, F. Alessandria, M. I. Martínez, M. Tenconi, B. X. Zhu, Carlo Ligi, M. Pavan, Vladimir Datskov, S. Di Domizio, Yu-Gang Ma, C. Zarra, B. K. Fujikawa, M. Vignati, A. De Biasi, T. I. Banks, A. Dally, Claudia Tomei, Alan R. Smith, S. Trentalange, G. Keppel, D. R. Artusa, Monica Sisti, L. Cardani, C. A. Whitten, L. Sparks, R. Reil, C. Rusconi, D. Lenz, T. Wise, CSNSM PS1, Centre de Spectrométrie Nucléaire et de Spectrométrie de Masse (CSNSM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11)-Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Centre Interdisciplinaire de Nanoscience de Marseille (CINaM), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), DAM Île-de-France (DAM/DIF), Direction des Applications Militaires (DAM), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), F. Alessandria, R. Ardito, D.R. Artusa, F.T. Avignone III, O. Azzolini, M. Balata, T.I. Bank, G. Bari, J. Beeman, F. Bellini, A. Bersani, M. Biassoni, T. Bloxham, C. Brofferio, C. Bucci, X.Z. Cai, L. Canonica, S. Capelli, L. Carbone, L. Cardani, M. Carrettoni, N. Casali, N. Chott, M. Clemenza, C. Cosmelli, O. Cremonesi, R.J. Creswick, I. Dafinei, A. Dally, V. Datskov, A. De Biasi, M.M. Deninno, S. Di Domizio, M.L. di Vacri, L. Ejzak, R. Faccini, D.Q. Fang, H.A. Farach, E. Ferri, F. Ferroni, E. Fiorini, M.A. Franceschi, S.J. Freedman, B.K. Fujikawa, A. Giachero, L. Gironi, A. Giuliani, J. Goett, A. Goodsell, P. Gorla, C. Gotti, E. Guardincerri, T.D. Gutierrez, E.E. Haller, K. Han, K.M. Heeger, H.Z. Huang, R. Kadel, K. Kazkaz, G. Keppel, L. Kogler, Yu. G. Kolomensky, D. Lenz, Y.L. Li, C. Ligi, X. Liu, Y.G. Ma, C. Maiano, M. Maino, M. Martinez, R.H. Maruyama, Y. Mei, N. Moggi, S. Morganti, T. Napolitano, S. Newman, S. Nisi, C. None, E.B. Norman, A. Nucciotti, F. Orio, D. Orlandi, J.L. Ouellet, M. Pallavicini, V. Palmieri, L. Pattavina, M. Pavan, M. Pedretti, G. Pessina, S. Pirro, E. Previtali, V. Rampazzo, R. Reil, F. Rimondi, C. Rosenfeld, C. Rusconi, S. Sangiorgio, N.D. Scielzo, M. Sisti, A.R. Smith, L. Spark, F. Stivanello, L. Taffarello, M. Tenconi, W.D. Tian, C. Tomei, S. Trentalange, G. Ventura, M. Vignati, B.S. Wang, H.W. Wang, C.A. Whitten Jr, T. Wise, A. Woodcraft, L. Zanotti, C. Zarra, B.X. Zhu, S. Zucchelli, Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU), Alessandria, F, Ardito, R, Artusa, D, Avignone III, F, Azzolini, O, Balata, M, Banks, T, Bari, G, Beeman, J, Bellini, F, Bersani, A, Biassoni, M, Bloxham, T, Brofferio, C, Bucci, C, Cai, X, Canonica, L, Capelli, S, Carbone, L, Cardani, L, Carrettoni, M, Casali, N, Chott, N, Clemenza, M, Cosmelli, C, Cremonesi, O, Creswick, R, Dafinei, I, Dally, A, Datskov, V, De Biasi, A, Deninno, M, Di Domizio, S, di Vacri, M, Ejzak, L, Faccini, R, Fang, D, Farach, H, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Goett, J, Goodsell, A, Gorla, P, Gotti, C, Guardincerri, E, Gutierrez, T, Haller, E, Han, K, Heeger, K, Huang, H, Kadel, R, Kazkaz, K, Keppel, G, Kogler, L, Kolomensky, Y, Lenz, D, Li, Y, Ligi, C, Liu, X, Ma, Y, Maiano, C, Maino, M, Martinez, M, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Napolitano, T, Newman, S, Nisi, S, Nones, C, Norman, E, Nucciotti, A, Orio, F, Orlandi, D, Ouellet, J, Pallavicini, M, Palmieri, V, Pattavina, L, Pavan, M, Pedretti, M, Pessina, G, Pirro, S, Previtali, E, Rampazzo, V, Reil, R, Rimondi, F, Rosenfeld, C, Rusconi, C, Sangiorgio, S, Scielzo, N, Sisti, M, Smith, A, Sparks, L, Stivanello, F, Taffarello, L, Tenconi, M, Tian, W, Tomei, C, Trentalange, S, Ventura, G, Vignati, M, Wang, B, Wang, H, Whitten Jr, C, Wise, T, Woodcraft, A, Zanotti, L, Zarra, C, Zhu, B, and Zucchelli, S

Subjects
Physics - Instrumentation and Detectors, Nuclear engineering, bolometer, neutrinoless double beta decay, radioactive background, surface contamination, FOS: Physical sciences, chemistry.chemical_element, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 01 natural sciences, Bolometer, Neutrinoless Double Beta Decay, Surface contamination, Radioactive background, High Energy Physics - Experiment, Nuclear physics, High Energy Physics - Experiment (hep-ex), CUORE, 0103 physical sciences, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Physics, 010308 nuclear & particles physics, Detector, Astronomy and Astrophysics, Instrumentation and Detectors (physics.ins-det), Contamination, Copper, NEUTRINOS, FIS/01 - FISICA SPERIMENTALE, RARE EVENTS, chemistry, DOUBLE-BETA DECAY, FIS/04 - FISICA NUCLEARE E SUBNUCLEARE
Abstract

In this article we describe the background challenges for the CUORE experiment posed by surface contamination of inert detector materials such as copper, and present three techniques explored to mitigate these backgrounds. Using data from a dedicated test apparatus constructed to validate and compare these techniques we demonstrate that copper surface contamination levels better than 10E-07 - 10E-08 Bq/cm2 are achieved for 238U and 232Th. If these levels are reproduced in the final CUORE apparatus the projected 90% C.L. upper limit on the number of background counts in the region of interest is 0.02-0.03 counts/keV/kg/y depending on the adopted mitigation technique., 10 pages, 6 figures, 6 tables

Published
2013

22. CALDER: neutrinoless double-beta decay identification in TeO[Formula: see text] bolometers with kinetic inductance detectors

Author

E S, Battistelli, F, Bellini, C, Bucci, M, Calvo, L, Cardani, N, Casali, M G, Castellano, I, Colantoni, A, Coppolecchia, C, Cosmelli, A, Cruciani, P, de Bernardis, S, Di Domizio, A, D'Addabbo, M, Martinez, S, Masi, L, Pagnanini, C, Tomei, and M, Vignati

Subjects
Regular Article - Experimental Physics
Abstract

Next-generation experiments searching for neutrinoless double-beta decay must be sensitive to a Majorana neutrino mass as low as 10\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\mathrm {~meV}$$\end{document}meV. CUORE , an array of 988 TeO\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$_2$$\end{document}2 bolometers being commissioned at Laboratori Nazionali del Gran Sasso, features an expected sensitivity of 50–130\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\mathrm {~meV}$$\end{document}meV at 90 % C.L. The background is expected to be dominated by \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\alpha $$\end{document}α radioactivity, and can be in principle removed by detecting the small amount of Cherenkov light emitted by the \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\beta $$\end{document}β signal. The Cryogenic wide-Area Light Detectors with Excellent Resolution project aims at developing a small prototype experiment consisting of TeO\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$_2$$\end{document}2 bolometers coupled to high-sensitivity light detectors based on kinetic inductance detectors. The R&D is focused on the light detectors in view of the implementation in a next-generation neutrinoless double-beta decay experiment.

Published
2015

23. The CUORE and CUORE-0 experiments at LNGS

Author

Guimin Zhang, C. Pira, R. J. Creswick, A. Leder, S. Di Domizio, V. Pettinacci, B. X. Zhu, Stefano Pirro, Laura Cardani, D. Santone, J. S. Wilson, Ioan Dafinei, C. Rosenfeld, Stefano Dell'Oro, P. Gorla, L. Pattavina, F. Ferroni, C. Tomei, S. L. Wagaarachchi, E. V. Hansen, C. Cosmelli, B. K. Fujikawa, Emanuele Ferri, X. Liu, F. Orio, L. Carbone, S. Zimmermann, C. Pagliarone, Yu. G. Kolomensky, Luigi Cappelli, A. Bersani, G. Keppe, G. Pessina, C. J. Davis, Massimiliano Clemenza, R. Hennings-Yeomans, S. Pozzi, A. Camacho, Monica Sisti, N. Moggi, B. S. Wang, C. Rusconi, T. Wise, C. Brofferio, P. J. Mosteiro, T. I. Banks, M. M. Deninno, M. Vignati, C. Nones, O. Azzolini, G. Piperno, Samuele Sangiorgio, A. Nucciotti, M. Pavan, H. W. Wang, N. D. Scielzo, Stefano Zucchelli, N. Chott, C. Alduino, M. Faverzani, L. Taffarello, Lucia Canonica, F. Bellini, L. Zanotti, Davide Chiesa, K. Alfonso, M. L. Di Vacri, K. E. Lim, Lorenzo Cassina, V. Singh, C. Bucci, Miriam Lucio Martinez, Lindley Winslow, M. Maino, Jeffrey W. Beeman, H. Z. Huang, M. Tenconi, L. Marini, Kevin Hickerson, S. Copello, E. Fiorini, Silvia Capelli, Paolo Carniti, A. D'Addabbo, A. Giuliani, Jonathan Ouellet, L. Gironi, F. T. Avignone, S. J. Freedman, G. Bari, S. Trentalange, R. W. Kadel, A. Caminata, Ezio Previtali, Marco Pallavicini, G. Fernandes, D. R. Artusa, S. Morganti, Jeremy S. Cushman, Carlo Ligi, A. R. Smith, C. Gotti, A. Woodcraft, A. Giachero, D. Q. Fang, L. Gladstone, T. D. Gutierrez, F. Terranova, A. Drobizhev, M. A. Franceschi, Y. Mei, Xi-Guang Cao, K. M. Heeger, E. E. Haller, Ke Han, A. Branca, Reina H. Maruyama, N. Casali, Oliviero Cremonesi, T. O'Donnell, Yu-Gang Ma, V. Palmieri, Eric B. Norman, T. Napolitano, M. Biassoni, Bravina, L, Foka, Y, Kabana, S, D'Addabbo, A, Alduino, C, Alfonso, K, Artusa, D, Avignone, F, Azzolini, O, Banks, T, Bari, G, Beeman, J, Bellini, F, Bersani, A, Biassoni, M, Branca, A, Brofferio, C, Bucci, C, Camacho, A, Caminata, A, Canonica, L, Cao, X, Capelli, S, Cappelli, L, Carbone, L, Cardani, L, Carniti, P, Casali, N, Cassina, L, Chiesa, D, Chott, N, Clemenza, M, Copello, S, Cosmelli, C, Cremonesi, O, Creswick, R, Cushman, J, Dafinei, I, Davis, C, Dell'Oro, S, Deninno, M, Di Domizio, S, Di Vacri, M, Drobizhev, A, Fang, D, Faverzani, M, Fernandes, G, Ferri, E, Ferroni, F, Fiorini, E, Franceschi, M, Freedman, S, Fujikawa, B, Giachero, A, Gironi, L, Giuliani, A, Gladstone, L, Gorla, P, Gotti, C, Gutierrez, T, Haller, E, Han, K, Hansen, E, Heeger, K, Hennings-Yeomans, R, Hickerson, K, Huang, H, Kadel, R, Keppel, G, Kolomensky, Y, Leder, A, Ligi, C, Lim, K, Liu, X, Ma, Y, Maino, M, Marini, L, Martinez, M, Maruyama, R, Mei, Y, Moggi, N, Morganti, S, Mosteiro, P, Napolitano, T, Nones, C, Norman, E, Nucciotti, A, O'Donnell, T, Orio, F, Ouellet, J, Pagliarone, C, Pallavicini, M, Palmieri, V, Pattavina, L, Pavan, M, Pessina, G, Pettinacci, V, Piperno, G, Pira, C, Pirro, S, Pozzi, S, Previtali, E, Rosenfeld, C, Rusconi, C, Sangiorgio, S, Santone, D, Scielzo, N, Singh, V, Sisti, M, Smith, A, Taffarello, L, Tenconi, M, Terranova, F, Tomei, C, Trentalange, S, Vignati, M, Wagaarachchi, S, Wang, B, Wang, H, Wilson, J, Winslow, L, Wise, T, Woodcraft, A, Zanotti, L, Zhang, G, Zhu, B, Zimmermann, S, Zucchelli, S, Centre de Sciences Nucléaires et de Sciences de la Matière (CSNSM), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Département de Physique des Particules (ex SPP) (DPP), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), D'Addabbo, A., Bravina, L., Alduino, C., Alfonso, K., Artusa, D. R., Avignone, F. T., Azzolini, O., Banks, T. I., Bari, G., Beeman, J. W., Bellini, F., Bersani, A., Biassoni, M., Branca, A., Brofferio, C., Bucci, C., A., Camacho, Caminata, A., Canonica, L., Cao, X. G., Capelli, S., Cappelli, L., Carbone, L., Cardani, L., Carniti, P., Casali, N., Cassina, L., Chiesa, D., Chott, N., Clemenza, M., Copello, S., Cosmelli, C., Cremonesi, O., Creswick, R. J., Cushman, J. S., Dafinei, I., Davis, C. J., Dell'Oro, S., Deninno, M. M., Di Domizio, S., Di Vacri, M. L., Drobizhev, A., Fang, D. Q., Faverzani, M., G., Fernande, Ferri, E., Ferroni, F., Fiorini, E., Franceschi, M. A., Freedman, S. J., Fujikawa, B. K., Giachero, A., Gironi, L., Giuliani, A., Gladstone, L., Gorla, P., Gotti, C., Gutierrez, T. D., Haller, E. E., Han, K., Hansen, E., Heeger, K. M., Hennings-Yeomans, R., Hickerson, K. P., Huang, H. Z., Kadel, R., Keppel, G., Kolomensky, Yu. G., Leder, A., Ligi, C., Lim, K. E., Liu, X., Ma, Y. G., Maino, M., Marini, L., Martinez, M., Maruyama, R. H., Mei, Y., Moggi, N., Morganti, S., Mosteiro, P. J., Napolitano, T., Nones, C., Norman, E. B., Nucciotti, A., O'Donnell, T., Orio, F., Ouellet, J. L., Pagliarone, C. E., Pallavicini, M., Palmieri, V., Pattavina, L., Pavan, M., Pessina, G., Pettinacci, V., Piperno, G., Pira, C., Pirro, S., Pozzi, S., Previtali, E., Rosenfeld, C., Rusconi, C., Sangiorgio, S., Santone, D., Scielzo, N. D., Singh, V., Sisti, M., Smith, A. R., Taffarello, L., Tenconi, M., Terranova, F., Tomei, C., Trentalange, S., Vignati, M., Wagaarachchi, S. L., Wang, B. S., Wang, H. W., Wilson, J., Winslow, L. A., Wise, T., Woodcraft, A., Zanotti, L., Zhang, G. Q., Zhu, B. X., S., Zimmermann, Zucchelli, S., Centre de Sciences Nucléaires et de Sciences de la Matière ( CSNSM ), Université Paris-Sud - Paris 11 ( UP11 ) -Institut National de Physique Nucléaire et de Physique des Particules du CNRS ( IN2P3 ) -Centre National de la Recherche Scientifique ( CNRS ), Département de Physique des Particules (ex SPP) ( DPP ), Institut de Recherches sur les lois Fondamentales de l'Univers ( IRFU ), Commissariat à l'énergie atomique et aux énergies alternatives ( CEA ) -Université Paris-Saclay-Commissariat à l'énergie atomique et aux énergies alternatives ( CEA ) -Université Paris-Saclay, and Département de Physique des Particules (ex SPP) (DPhP)

Subjects
Cryostat, Physics - Instrumentation and Detectors, QC1-999, FOS: Physical sciences, double beta decay, Te-130, fabrication, 7. Clean energy, 01 natural sciences, tellurium: oxygen, crystal, law.invention, Nuclear physics, Physics and Astronomy (all), CUORE, bolometer, law, Observatory, Double Beta Decay: 0 neutrino | CUORE Experiment | | CUORE-0 Experiment | Activity report | performance | bolometer | cryogenics | crystal | tellurium: oxygen | fabrication, 0103 physical sciences, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], 010306 general physics, [ PHYS.PHYS.PHYS-INS-DET ] Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], 010303 astronomy & astrophysics, activity report, Physics, Bolometer, Instrumentation and Detectors (physics.ins-det), cryogenics, performance
Abstract

The Cryogenic Underground Observatory for Rare Events (CUORE) is a 1-ton scale bolometric experiment devoted to the search of the neutrinoless double-beta decay (0{\nu}\b{eta}\b{eta}) in 130Te. The CUORE detector consists of an array of 988 TeO2 crystals operated at 10 mK. CUORE-0 is the CUORE demonstrator: it has been built to test the performance of the upcoming CUORE experiment and represents the largest 130Te bolometric setup ever operated. CUORE-0 has been running at Laboratori Nazionali del Gran Sasso (Italy) from 2013 to 2015. The final CUORE-0 analysis on 0{\nu}\b{eta}\b{eta} and the corresponding detector performance are presented. The present status of the CUORE experiment, now in its final construction and commissioning phase, are discussed. The results from assembly of the detector and the commissioning of the cryostat are reported., Comment: 10 pages, 7 figures, ICNFP2016 Proceeding

Published
2017

24. CALDER: cryogenic light detectors for background free searches

Author

L. Cardani, E. Battistelli, F. Bellini, C. Bucci, M. Calvo, A. Cruciani, M.G. Castellano, I. Colantoni, A. Coppolecchia, C. Cosmelli, A. D'Addabbo, P. de Bernardis, S. Di Domizio, S. Masi, D. Pinci, C. Tomei, and M. Vignati

Published
2014

25. Study of coincidences between resonant gravitational wave detectors

Author

P Astone, M Bassan, P Bonifazi, P Carelli, E Coccia, C Cosmelli, S D'Antonio, V Fafone, G Federici, A Marini, Y Minenkov, I Modena, G Modestino, A Moleti, G V Pallottino, G Pizzella, L Quintieri, F Ronga, R Terenzi, M Visco, and L Votano

Subjects
Physics, Settore FIS/05 - Astronomia e Astrofisica, Physics and Astronomy (miscellaneous), Physics::Instrumentation and Detectors, Gravitational wave, Settore FIS/01 - Fisica Sperimentale, Detector, FOS: Physical sciences, Astronomy, General Relativity and Quantum Cosmology (gr-qc), General Relativity and Quantum Cosmology
Abstract

Coincidences are searched with the cryogenic resonant gravitational wave detectors EXPLORER and NAUTILUS, during a period of about six months (2 June-14 December 1998) for a total measuring time of 94.5 days, with the purpose to study new algorithms of analysis, based on the physical characteristics of the detectors., revised version (minor changes and a comment in the conclusion)

Published
2000

26. Return current in hysteretic Josephson junctions: Experimental distribution in the thermal activation regime

Author

Fabio Chiarello, Guido Torrioli, P. Carelli, M. G. Castellano, and C. Cosmelli

Subjects
Pi Josephson junction, Physics, Josephson effect, Condensed matter physics, Thermal, General Physics and Astronomy, Macroscopic quantum phenomena, Function (mathematics), Dissipation, Magnetic field, Voltage
Abstract

We present an experimental study on the retrapping process of a hysteretic, high-quality Josephson junction; namely, we have measured the distribution of the values at which the junction switches back from the voltage state to the zero-voltage state, as a function of the applied magnetic field. While the opposite process (escape from the zero-voltage state) has been extensively studied in the past, both from the theoretical and the experimental point of view, little is found in the literature on the retrapping process. In terms of the tilted washboard potential, the process corresponds to the retrapping from the running state to a locked state in a potential well. The interest of the measurements is in the fact that the value of the return current can be directly related to the dissipation in the junction. While the deterministic behavior, experimentally measured through the I–V curve, appears to be in agreement with the theoretical predictions, even in minor details, the statistical behavior is strongly different from what is expected. The disagreement is found even in zero-applied magnetic field and it cannot be attributed to external noise in the system. From the experimental statistical properties, we find values for the effective dissipation much lower than those obtained from the deterministic curves, a result which could be of interest in experiments on the observation of macroscopic quantum phenomena.

Published
1999

27. The effective dissipation in Nb/AlOx/Nb Josephson tunnel junctions by return current measurements

Author

C. Cosmelli, Ciro Nappi, Guido Torrioli, R. Cristiano, M. G. Castellano, and Luigi Frunzio

Subjects
Josephson effect, Physics, Condensed matter physics, Niobium, General Physics and Astronomy, chemistry.chemical_element, BCS theory, Dissipation, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Coherence length, Tunnel effect, chemistry, Condensed Matter::Superconductivity, Quasiparticle, Dissipation factor
Abstract

Measurements of temperature dependence of the return current in high quality Nb/AlOx/Nb Josephson junctions are presented. From the experimental data, we obtain the effective resistance, i.e., the effective dissipation, for the retrapping process, according to the generalized resistively shunted junction model proposed by Chen, Fisher, and Leggett. We present a careful analysis, based on a comparison between the measured temperature dependencies of both the return and the quasiparticle tunneling current. We find that the junction subgap conductance, which includes the quasiparticle and the quasiparticle-pair interference terms, is responsible for the return process. The measurements have been performed on various samples, in a wide range of critical current densities from 50 to 2250 A/cm2, covering different damping regimes and spanning over the high and low temperature limits. Junctions with low critical current density show ideal dissipation which makes the return current scale with temperature accordin...

Published
1997

28. Magnetic field dependence of thermal excitations in Josephson junctions

Author

G. Rotoli, Matteo Cirillo, P. Carelli, C. Cosmelli, Fabio Chiarello, Guido Torrioli, M. G. Castellano, Castellano, M. G., Torrioli, G, Cosmelli, C, Chiarello, F, Cirillo, M, Carelli, P, and Rotoli, Giacomo

Subjects
Josephson effect, Physics, Condensed matter physics, Niobium, chemistry.chemical_element, Activation energy, Effective temperature, Thermodynamic temperature, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Magnetic field, Pi Josephson junction, chemistry, Condensed Matter::Superconductivity, Thermal, Electrical and Electronic Engineering
Abstract

We have measured the rate of escape out of the zero-voltage state in Josephson tunnel junctions as a function of the applied magnetic field. A marked difference is found in the behaviour of long and small junctions. In all cases, the statistical distribution of the switching currents can be described using a Kramers model for the escape process, where the barrier to be overcome is the Josephson barrier and the activation energy is due to an effective temperature T/sub e/. For small junctions T/sub e/ coincides, as expected, with the thermodynamic temperature, regardless of the applied magnetic field. For long junctions instead it is found that the escape temperature depends markedly on the magnetic field and on the junction geometry (inline or overlap), suggesting a close relationship with the magnetic field distribution inside the junction.

Published
1997

29. A New Flux/Phase Qubit With Integrated Readout

Author

Francesco Mattioli, Roberto Leoni, M. G. Castellano, Guido Torrioli, Stefano Poletto, Fabio Chiarello, P. Carelli, C. Cosmelli, D. Simeone, and M. Di Bucchianico

Subjects
Physics, Superconductivity, Josephson effect, Flux qubit, Charge qubit, Condensed matter physics, josephson, qubit, squid, superconductivity, Flux, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, law.invention, Phase qubit, SQUID, law, Condensed Matter::Superconductivity, Qubit, Electrical and Electronic Engineering
Abstract

We propose a new scheme for a flux/phase qubit, based on a double-SQUID modified to achieve a direct readout of the flux state. The readout is performed by inserting a large Josephson junction in the SQUID loop; the junction is biased by an external current and switches from the zero-voltage to the running state depending on the flux state of the qubit. We report recent results concerning the theoretical behavior and the experimental characterization at 4.2 K of the device, which has been realized with Nb/AlOx/Nb trilayer technology.

Published
2005

30. Coherent quantum manipulation of superconducting qubits by fast flux pulses: decoherence, adiabaticity and speed issues

Author

F Chiarello 1, M G Castellano 1, G Torrioli 1, C Cosmelli 2, and P Carelli 3

Abstract

A double SQUID can be used as a solid state flux qubit. Its behavior is described by an effective potential the shape of which can be modified by two independent bias magnetic fluxes. In particular, it is possible to pass from a single-well to a double-well shape, and it is also possible to modify its symmetry/asymmetry. A rapid modification of the potential allows the manipulation of the quantum state in a very fast manner: we observed coherent oscillations with frequencies up to 70GHz, to be compared with the typical oscillations obtained by microwave manipulations on similar systems, below 1GHz. This is an interesting advantage from the point of view of quantum computing, since for similar decoherence times a greater speed means a large number of possible coherent operations. Moreover, the manipulation based on fast flux pulses allowed a deep insight in decoherence mechanism acting on the system. The drawback of this scheme concerns the fact that the manipulation must be in the same time non-adiabatic (for the two lower energy levels, the computational states), and adiabatic (for the upper ones). This is possible thanks to the energy level structure, but requires an accurate characterization of the system. We present principles and recent results, and discuss issues and perspectives about this scheme.

Published
2013

31. Observation of 65GHz coherent oscillation in a superconducting flux qubit manipulated by pulses

Author

F Chiarello 1, M G Castellano 1, G Torrioli 1, C Cosmelli 2, and P Carelli 3

Abstract

A superconducting flux qubit can be manipulated by fast modification of its potential, with a rapid transition from a double well to a single well shape, and coming back to the initial condition. This mechanism is based on a nontrivial quantum phenomena, involving "partial" Landau-Zener transitions, coherent evolution in an harmonic potential and quantum interference. The study of this system enables a deep insight in decoherence mechanisms typical of superconducting qubits. Moreover, this procedure allows quantum operations with extreme high speeds, not possible with other standard manipulations. We present the experimental observation of coherent oscillations showing tunable frequencies with a 65GHz top value.

Published
2013

32. 'Superconducting qubit manipulated by fast pulses: experimental observation of distinct decoherence regimes'

Author

F. Chiarello, M.G. Castellano, C. Cosmelli, and G. Torrioli

Subjects
Superconductors Qubits and Circuits, Quantum Information Processing, Quantum Physics
Abstract

A double SQUID qubit (Superconducting Quantum Interference Device) can be handled by applying microwave trains, but also by using fast flux pulses. In this second case the manipulation is based on the fast and radical modification of the qubit potential shape that induces non-adiabatic transitions between the computational states (the two lowest energy eigenstates), still avoiding transitions to upper levels. This modality is interesting because it allows faster operations with respect to other techniques, but also because it gives access to interesting nontrivial physical features, concerning in particular decoherence and adiabaticity. About decoherence, we observed experimentally the existence of an "optimal" bias region and the transition between two distinct decoherence regimes. These results can be explained by considering the effect of first and second order slow fluctuations which dominate on high frequency noise contributions. This allows a deep insight in the qubit decoherence mechanisms.

Published
2012
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35. Correlation between the Maryland and Rome gravitational-wave detectors and the Mont Blanc, Kamioka and IMB particle detectors during SN 1987 A

Author

M. Visco, C. Castagnoli, E. Coccia, J. Weber, G. C. Trinchero, Ivo Modena, W. Fulgione, S. Frasca, G. Bologna, Ettore Majorana, P. Rapagnani, C. Cosmelli, S. Vernetto, P. Galeotti, F. Ricci, D. Gretz, Giovanni Vittorio Pallottino, G. Wilmot, M. Bassan, Giovanni Badino, O. Saavedra, M. G. Castellano, G. Pizzella, Marco Aglietta, P. Astone, Antonella Castellina, and P. Bonifazi

Subjects
Physics, Wave detection, Gravitational wave, Detector, PACS 04.80 Experimental tests of general relativity and observations of gravitational radiation, PACS 97.60.Bw Supernovae, Particle, High Energy Physics::Experiment, Astrophysics, Mont blanc, Particle detector
Abstract

Following a previously found correlation between the gravitational-wave detectors and the Mont Blanc particle detector, we have searched for a similar correlation between the data of the experiments mentioned in the title. We have found that both the Kamioka and the IMB data have a correlation with the gravitational-wave data that occurs with the same characteristics and at the same time of that already found with Mont Blanc. This correlation extends for a period of one or two hours centred at the hour 2∶45 UT of 23 February 1987. It shows that the particle detector signals are delayed with respect to the gravitational-wave detector signals by (1.2±0.5) s. The probability that the additional correlation due to Kamioka and IMB is only accidental is estimated of the order of 10−3 or 10−4.

Published
1991

36. First Cooling Below 0.1 K of the New Gravitational-Wave Antenna 'Nautilus' of the Rome Group

Author

Giovanni Vittorio Pallottino, M. Visco, E. Coccia, F. Ricci, P. Astone, F. Bronzini, V. Fafone, Ettore Majorana, C. Cosmelli, P. Rapagnani, P. Bonifazi, M. Bassan, S. Frasca, M. G. Castellano, G. Pizzella, and I. Modena

Subjects
Physics, biology, General relativity, Group (mathematics), Gravitational wave, Astrophysics::Instrumentation and Methods for Astrophysics, General Physics and Astronomy, Astronomy, Cryogenics, Astrophysics, biology.organism_classification, cryogenics, Physics::Atomic Physics, Nautilus, Antenna (radio), Computer Science::Information Theory
Abstract

We report on the first cryogenic test at ultralow temperature of the new gravitational-wave antenna "Nautilus" of the Rome group. The 2390 kg Al 5056 cylindrical-bar antenna has been cooled to a temperature of 95 mK.

Published
1991

37. Free Parameters in the Matching Conditions for a Cryogenic Gravitational Radiation Detector

Author

C. Cosmelli

Subjects
Physics, Optics, Transducer, Current-feedback operational amplifier, Gravitational wave, business.industry, Detector, General Physics and Astronomy, Sensitivity (control systems), Antenna (radio), business, Capacitance, Free parameter
Abstract

The sensitivity of a resonant gravitational wave antenna coupled with a capacitive transducer to a current amplifier is written in terms of all the parameters of the system. The matching conditions that must be realized to obtain the maximum theoretical sensitivity are written as a function of the physical parameters of the transducer. It is shown that the energy coupling factor is independent of the mass as well as of the capacitance of the transducer. The only free parameter then, apart from a weak dependence on the material used, is shown to be the gap of the capacitor. This dependence suggests the strategy to be used to obtain the best sensitivity for the present systems.

Published
1991

38. Coincidences among the data recorded by the baksan, kamioka and mont blanc underground neutrino detectors, and by the Maryland and Rome gravitational-wave detectors during Supernova 1987 A

Author

V. A. Kudryatzev, Antonella Castellina, Giovanni Vittorio Pallottino, S. Frasca, E. Amaldi, I. Modena, G. Wilmot, M. G. Castellano, M. Visco, P. Bonifazi, G. Pizzella, F. F. Khalchukov, O. Saavedra, P. Galeotti, M. Bassan, S. Vernetto, P. Rapagnani, Marco Aglietta, P. Astone, O. G. Ryazhskaya, C. Castagnoli, G. T. Zatsepin, D. Gretz, Giovanni Badino, V. G. Ryassny, E. Coccia, P. V. Kortchaguin, V. F. Yakushev, V. L. Dadykin, G. C. Trinchero, I. V. Korolkova, G. Bologna, J. Weber, F. Ricci, A. S. Malguin, C. Cosmelli, and W. Fulgione

Subjects
Physics, Supernova, Neutrino detector, Gravitational wave, Detector, Astronomy, Statistical analysis, Astrophysics, Neutrino, Mont blanc, Particle detector
Abstract

The data recorded with the neutrino detectors at Mont Blanc, Kamioka, Baksan and with the gravitational-wave detectors in Maryland and Rome have been analysed searching for correlations associated with SN 1987 A, without presuming or excluding hypotheses for correlations due to neutrinos and gravitational waves. The statistical analysis has been based on a previous analysis that showed a correlation among Maryland, Rome and Mont Blanc with a probability to be accidental less than 10−5. Independent correlations are found during a period of one or two hours, around the Mont Blanc 5ν burst (2h 52 min 36 s UT), among the various sets of data: Mont Blanc-Baksan with a probability to be accidental of the order ofp∼4·10−3, Mont Blanc-Kamioka withp∼4·10−3, Maryland-Rome-Kamioka withp∼5·10−4, Maryland-Rome-Baksan withp∼5·10−2. It is remarkable that the events from all the neutrino detectors follow the signals from the g.w. detectors by a time of the order of 1/2 or 1 s. At present we will not give a physical interpretation of the observed correlations which have strong statistical significance.

Published
1991

44. CUORICINO AND CUORE R&D

Author

Marco Barucci, C. Rosenfeld, Yu. G. Kolomenski, P. Gorla, F. Ferroni, H. A. Farach, M. Pavan, A. Giuliani, E. Longo, L. Torres, A. Giachero, K. M. Heeger, Samuele Sangiorgio, Stefano Nisi, E. Guardincerri, E. Fiorini, M. Diemoz, M. Olcese, A. Nucciotti, S. J. Freedmann, N. Xu, D. Gutierrez, L. Carbone, C. Gargiullo, Massimiliano Clemenza, Monica Sisti, R. J. Creswick, Oliviero Cremonesi, F. T. Avignone, G. Ventura, I. G. Irastorza, S. Pirro, S. Morganti, I. Dafinei, Giulio Maier, C. Brofferio, P. Ottonello, Cristián Martínez, M. Balata, C. Bucci, A. R. Smith, Reina H. Maruyama, V. Palmieri, S. Cebrián, M. J. Dolinski, C. Cosmelli, E. E. Haller, Simone Capelli, Lara Risegari, Eric B. Norman, S. Cuneo, F. Bellini, Jeffrey W. Beeman, S. Di Domizio, C. Zarra, M. Vignati, F. Alessandria, E. Previtali, L. Zanotti, M. Pedretti, G. Pessina, C. Arnaboldi, Raffaele Ardito, C. Nones, Marco Pallavicini, and I. C. Bandac

Subjects
Physics, Particle physics, CUORE, law, Double beta decay, Bolometer, Neutrino, law.invention
Published
2007

45. Catastrophe observation in a Josephson-junction system

Author

P. Carelli, Francesco Mattioli, M. Cirillo, C. Cosmelli, Giorgio Frossati, Guido Torrioli, Stefano Poletto, Roberto Leoni, M. G. Castellano, Fabio Chiarello, Niels Grønbech-Jensen, and A. de Waard

Subjects
Josephson effect, FLUX, State variable, FOS: Physical sciences, General Physics and Astronomy, Butterfly catastrophe, Potential energy, Quantum computers, Quantum electronics, SQUIDs, Control parameters, Potential energy wells, Josephson junction devices, Settore FIS/03 - Fisica della Materia, Superconductivity (cond-mat.supr-con), Phase qubit, Pi Josephson junction, Quantum mechanics, Quantum, Physics, Condensed Matter - Superconductivity, STATE, Condensed Matter - Other Condensed Matter, Qubit, Other Condensed Matter (cond-mat.other), Coherence (physics)
Abstract

We report on a direct quantitative comparison between Thom's general catastrophe theory for systems presenting discontinuous behavior and experimental reality. It is demonstrated that the model provides a striking quantitative description of the measured experimental features of the complex nonlinear system generating the most appealing class of sensors and devices nowadays used in experiments, namely the Superconducting Quantum Interference Devices (SQUIDs). The parameter space of the SQUID system that we investigate displays all the features associated with a butterfly catastrophe, namely a catastrophe expected for a system having four control parameters and one state variable., 13 figures in A4 pdf format including three figures. Article submitted for publication

Published
2007

46. An active‐shield method for the reduction of surface contamination in CUORE

Author

M. Pedretti, F. Alessandria, R. Ardito, C. Arnaboldi, F. T. Avignone, M. Balata, I. Bandac, M. Barucci, J. W. Beemann, F. Bellini, C. Brofferio, C. Bucci, S. Capelli, L. Carbone, S. Cebrian, M. Clemenza, C. Cosmelli, S. Cuneo, O. Cremonesi, R. J. Creswick, I. Dafinei, S. Di Domizio, S. Diemoz, M. J. Dolinski, H. A. Farach, F. Ferroni, E. Fiorini, L. Foggetta, S. J. Freedman, C. Gargiulo, A. Giachero, E. Guardincerri, A. Giuliani, P. Gorla, T. D. Gutierrez, E. E. Haller, K. M. Heeger, I. G. Irastorza, Yu. G. Kolomenski, E. Longo, G. Maier, R. Maruyama, C. Martinez, S. Morganti, S. Nisi, C. Nones, E. B. Norman, A. Nucciotti, M. Olcese, P. Ottonello, M. Pallavicini, E. Palmieri, M. Pavan, G. Pessina, S. Pirro, E. Previtali, L. Risegari, C. Rosenfeld, C. Salvioni, S. Sangiorgio, M. Sisti, A. R. Smith, L. Torres, G. Ventura, M. Vignati, N. Xu, C. Zarra, L. Zanotti, Pedretti, M, Alessandria, F, Ardito, R, Arnaboldi, C, Avignone III, F, Balata, M, Bandac, I, Barucci, M, Beeman, J, Bellini, F, Brofferio, C, Bucci, C, Capelli, S, Carbone, L, Cebrian, S, Clemenza, M, Cosmelli, C, Cuneo, S, Cremonesi, O, Creswick, R, Dafinei, I, Di Domizio, S, Diemoz, S, Dolinski, M, Farach, H, Ferroni, F, Fiorini, E, Foggetta, L, Freedman, S, Gargiulo, C, Giachero, A, Guardincerri, E, Giuliani, A, Gorla, P, Gutierrez, T, Haller, E, Heeger, K, Irastorza, I, Kolomenski, Y, Longo, E, Maier, G, Maruyama, R, Martinez, C, Morganti, S, Nisi, S, Nones, C, Norman, E, Nucciotti, A, Olcese, M, Ottonello, P, Pallavicini, M, Palmieri, E, Pavan, M, Pessina, G, Pirro, S, Previtali, E, Risegari, L, Rosenfeld, C, Salvioni, C, Sangiorgio, S, Sisti, M, Smith, A, Torres, L, Ventura, G, Vignati, M, Xu, N, Zarra, C, and Zanotti, L

Subjects
Physics, Bolometer, Detector, Cryogenic detector, Double beta decay, law.invention, Nuclear physics, CUORE, law, Shield, Neutrino, Electromagnetic shielding, FIS/04 - FISICA NUCLEARE E SUBNUCLEARE, Radioactive decay
Abstract

The main goal of the CUORE experiment is to search for the neutrinoless double beta decay of 130Te. As it is a rare nuclear decay, the sensitivity of the experiment strongly depends on the background level in the transition energy region. In this paper we describe the R&D work performed to develop an active method for the reduction of radioactive background in CUORE. The idea is to reject events originated by surface contamination in large mass bolometric detectors by using bolometers sensitive to surface events. Results obtained with the first prototypes and tests made with large mass surface sensitive bolometers will be reported.

Published
2007

48. EXPLORER AND NAUTILUS: PRESENT STATUS

Author

Y. Minenkov, M. Bassan, F.J. Ronga, M. G. Castellano, G. Pizzella, Arturo Moleti, G. Giordano, Andrea Carlo Marini, Lina Quintieri, Giovanni Vittorio Pallottino, P. Astone, R. Terenzi, D. Babusci, E. Coccia, V. Fafone, P. Bonifazi, A. Rocchi, Ivo Modena, G. Cavallari, P. Modestino, S. D'Antonio, P. Carelli, C. Cosmelli, Guido Torrioli, and M. Visco

Subjects
Physics, Large Hadron Collider, biology, Duty cycle, Gravitational wave, Detector, Bandwidth (signal processing), Astronomy, Electronics, Nautilus, biology.organism_classification, Continuous data
Abstract

We report on the present status of the resonant gravitational waves detectors EXPLORER and NAUTILUS operated by the ROG collaboration at CERN and at the INFN Prascati National Laboratories respectively. EXPLORER has been operating in continuous data taking for three years. NAUTILUS during 2002 underwent a partial overhaul of its read-out electronics. The results obtained since May 2003 show a considerable improvement in the performances of the apparatus. Both the detectors exhibit an unprecedented useful bandwidth: in over 30 Hz their spectral sensitivities are better than 10~/ \/Hz with a duty cycle only limited by cryogenic operations.

Published
2006

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