An energy-dependent electro-thermal response model of CUORE cryogenic calorimeter

D.Q. Adams; C. Alduino; K. Alfonso; F.T. Avignone; O. Azzolini; G. Bari; F. Bellini; G. Benato; M. Beretta; M. Biassoni; A. Branca; C. Brofferio; C. Bucci; J. Camilleri; A. Caminata; A. Campani; L. Canonica; X.G. Cao; S. Capelli; C. Capelli; L. Cappelli; L. Cardani; P. Carniti; N. Casali; E. Celi; D. Chiesa; M. Clemenza; S. Copello; O. Cremonesi; R.J. Creswick; A. D'Addabbo; I. Dafinei; F. Del Corso; S. Dell'Oro; S. Di Domizio; S. Di Lorenzo; 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; S. Ghislandi; A. Giachero; A. Gianvecchio; L. Gironi; A. Giuliani; P. Gorla; C. Gotti; T.D. Gutierrez; K. Han; E.V. Hansen; K.M. Heeger; R.G. Huang; H.Z. Huang; J. Johnston; G. Keppel; Yu.G. Kolomensky; R. Kowalski; M. Li; R. Liu; L. Ma; Y.G. Ma; L. Marini; R.H. Maruyama; D. Mayer; Y. Mei; S. Morganti; T. Napolitano; M. Nastasi; J. Nikkel; C. Nones; E.B. Norman; A. Nucciotti; I. Nutini; T. O'Donnell; M. Olmi; 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; S. Quitadamo; A. Ressa; C. Rosenfeld; 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; S. Zucchelli; The CUORE Collaboration

doi:10.1088/1748-0221/17/11/P11023

Journal of Instrumentation

paper

An energy-dependent electro-thermal response model of CUORE cryogenic calorimeter

D.Q. Adams¹, C. Alduino¹, K. Alfonso^2,11, F.T. Avignone III¹, O. Azzolini³, G. Bari⁴, F. Bellini^5,6, G. Benato⁷, M. Beretta⁸, M. Biassoni⁹, A. Branca^10,9, C. Brofferio^10,9, C. Bucci⁷, J. Camilleri¹¹, A. Caminata¹², A. Campani^13,12, L. Canonica^14,7, X.G. Cao¹⁵, S. Capelli^10,9, C. Capelli¹⁶, L. Cappelli⁷, L. Cardani⁶, P. Carniti^10,9, N. Casali⁶, E. Celi^17,7, D. Chiesa^10,9, M. Clemenza⁹, S. Copello^13,12, O. Cremonesi⁹, R.J. Creswick¹, A. D'Addabbo⁷, I. Dafinei⁶, F. Del Corso^18,4, S. Dell'Oro^10,9, S. Di Domizio^13,12, S. Di Lorenzo⁷, V. Dompè^5,6, D.Q. Fang¹⁵, G. Fantini^5,6, M. Faverzani^10,9, E. Ferri⁹, F. Ferroni^17,6, E. Fiorini^9,10, M.A. Franceschi¹⁹, S.J. Freedman^16,8, S.H. Fu¹⁵, B.K. Fujikawa¹⁶, S. Ghislandi^17,7, A. Giachero^10,9, A. Gianvecchio¹⁰, L. Gironi^10,9, A. Giuliani²⁰, P. Gorla⁷, C. Gotti⁹, T.D. Gutierrez²¹, K. Han²², E.V. Hansen⁸, K.M. Heeger²³, R.G. Huang⁸, H.Z. Huang², J. Johnston¹⁴, G. Keppel³, Yu.G. Kolomensky^8,16, R. Kowalski²⁴, M. Li^8,14, R. Liu²³, L. Ma², Y.G. Ma¹⁵, L. Marini^17,7, R.H. Maruyama²³, D. Mayer¹⁴, Y. Mei¹⁶, S. Morganti⁶, T. Napolitano¹⁹, M. Nastasi^10,9, J. Nikkel²³, C. Nones²⁵, E.B. Norman^26,27, A. Nucciotti^10,9, I. Nutini^10,9, T. O'Donnell¹¹, M. Olmi⁷, J.L. Ouellet¹⁴, S. Pagan²³, C.E. Pagliarone^7,28, L. Pagnanini⁷, M. Pallavicini^13,12, L. Pattavina⁷, M. Pavan^10,9, G. Pessina⁹, V. Pettinacci⁶, C. Pira³, S. Pirro⁷, S. Pozzi^10,9, E. Previtali^10,9, A. Puiu^17,7, S. Quitadamo^17,7, A. Ressa^5,6, C. Rosenfeld¹, S. Sangiorgio²⁶, B. Schmidt¹⁶, N.D. Scielzo²⁶, V. Sharma¹¹, V. Singh⁸, M. Sisti⁹, D. Speller²⁴, P.T. Surukuchi²³, L. Taffarello²⁹, F. Terranova^10,9, C. Tomei⁶, K.J. Vetter^8,16, M. Vignati^5,6, S.L. Wagaarachchi^8,16, B.S. Wang^26,27, B. Welliver^8,16, J. Wilson¹, K. Wilson¹, L.A. Winslow¹⁴, S. Zimmermann³⁰, S. Zucchelli^18,4 and The CUORE Collaboration

Published 17 November 2022 • © 2022 IOP Publishing Ltd and Sissa Medialab
Journal of Instrumentation, Volume 17, November 2022 Citation D.Q. Adams et al 2022 JINST 17 P11023 DOI 10.1088/1748-0221/17/11/P11023

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cuore-spokesperson@lngs.infn.it

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¹ Department of Physics and Astronomy, University of South Carolina, Columbia, SC 29208, U.S.A.

² Department of Physics and Astronomy, University of California, Los Angeles, CA 90095, U.S.A.

³ INFN — Laboratori Nazionali di Legnaro, Legnaro (Padova) I-35020, Italy

⁴ INFN — Sezione di Bologna, Bologna I-40127, Italy

⁵ Dipartimento di Fisica, Sapienza Università di Roma, Roma I-00185, Italy

⁶ INFN — Sezione di Roma, Roma I-00185, Italy

⁷ INFN — Laboratori Nazionali del Gran Sasso, Assergi (L'Aquila) I-67100, Italy

⁸ Department of Physics, University of California, Berkeley, CA 94720, U.S.A.

⁹ INFN — Sezione di Milano Bicocca, Milano I-20126, Italy

¹⁰ Dipartimento di Fisica, Università di Milano-Bicocca, Milano I-20126, Italy

¹¹ Center for Neutrino Physics, Virginia Polytechnic Institute and State University, Blacksburg, Virginia 24061, U.S.A.

¹² INFN — Sezione di Genova, Genova I-16146, Italy

¹³ Dipartimento di Fisica, Università di Genova, Genova I-16146, Italy

¹⁴ Massachusetts Institute of Technology, Cambridge, MA 02139, U.S.A.

¹⁵ Key Laboratory of Nuclear Physics and Ion-beam Application (MOE), Institute of Modern Physics, Fudan University, Shanghai 200433, China

¹⁶ Nuclear Science Division, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, U.S.A.

¹⁷ Gran Sasso Science Institute, L'Aquila I-67100, Italy

¹⁸ Dipartimento di Fisica e Astronomia, Alma Mater Studiorum — Università di Bologna, Bologna I-40127, Italy

¹⁹ INFN — Laboratori Nazionali di Frascati, Frascati (Roma) I-00044, Italy

²⁰ Université Paris-Saclay, CNRS/IN2P3, IJCLab, 91405 Orsay, France

²¹ Physics Department, California Polytechnic State University, San Luis Obispo, CA 93407, U.S.A.

²² INPAC and School of Physics and Astronomy, Shanghai Jiao Tong University, Shanghai Laboratory for Particle Physics and Cosmology, Shanghai 200240, China

²³ Wright Laboratory, Department of Physics, Yale University, New Haven, CT 06520, U.S.A.

²⁴ Department of Physics and Astronomy, The Johns Hopkins University, 3400 North Charles Street, Baltimore, MD, 21211

²⁵ IRFU, CEA, Université Paris-Saclay, F-91191 Gif-sur-Yvette, France

²⁶ Lawrence Livermore National Laboratory, Livermore, CA 94550, U.S.A.

²⁷ Department of Nuclear Engineering, University of California, Berkeley, CA 94720, U.S.A.

²⁸ Dipartimento di Ingegneria Civile e Meccanica, Università degli Studi di Cassino e del Lazio Meridionale, Cassino I-03043, Italy

²⁹ INFN — Sezione di Padova, Padova I-35131, Italy

³⁰ Engineering Division, Lawrence Berkeley National Laboratory, Berkeley, CA 94720, U.S.A.

Dates

Received 2 August 2022
Accepted 19 October 2022
Published 17 November 2022

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Abstract

The Cryogenic Underground Observatory for Rare Events (CUORE) is the most sensitive experiment searching for neutrinoless double-beta decay (0νββ) in ¹³⁰Te. CUORE uses a cryogenic array of 988 TeO₂ calorimeters operated at ∼10 mK with a total mass of 741 kg. To further increase the sensitivity, the detector response must be well understood. Here, we present a non-linear thermal model for the CUORE experiment on a detector-by-detector basis. We have examined both equilibrium and dynamic electro-thermal models of detectors by numerically fitting non-linear differential equations to the detector data of a subset of CUORE channels which are well characterized and representative of all channels. We demonstrate that the hot-electron effect and electric-field dependence of resistance in NTD-Ge thermistors alone are inadequate to describe our detectors' energy-dependent pulse shapes. We introduce an empirical second-order correction factor in the exponential temperature dependence of the thermistor, which produces excellent agreement with energy-dependent pulse shape data up to 6 MeV. We also present a noise analysis using the fitted thermal parameters and show that the intrinsic thermal noise is negligible compared to the observed noise for our detectors.

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