Searching for New Physics in two-neutrino double beta decay with CUPID

Armatol, A; Armengaud, E; Armstrong, W; Augier, C; T Avignone, F; Azzolini, O; Barabash, A; Bari, G; Barresi, A; Baudin, D; Bellini, F; Benato, G; Beretta, M; Berg??, L; Biassoni, M; Billard, J; Boldrini, V; Branca, A; Brofferio, C; Bucci, C; Camilleri, J; Capelli, S; Cappelli, L; Cardani, L; Carniti, P; Casali, N; Cazes, A; Celi, E; Chang, C; Chapellier, M; Charrier, A; Chiesa, D; Clemenza, M; Colantoni, I; Collamati, F; Copello, S; Cremonesi, O; J Creswick, R; Cruciani, A; D'Addabbo, A; D'Imperio, G; Dafinei, I; A Danevich, F; M de Combarieu,; M De Jesus,; P de Marcillac,; Dell'Oro, S; Di Domizio, S.; Dompè, V; Drobizhev, A; Dumoulin, L; Fantini, G; Faverzani, M; Ferri, E; Ferri, F; Ferroni, F; Figueroa-Feliciano, E; Formaggio, J; Franceschi, A; Fu, C; Fu, S; K Fujikawa, B; Gascon, J; Ghislandi, S; Giachero, A; Gironi, L; Giuliani, A; Gorla, P; Gotti, C; Gras, P; Gros, M; D Gutierrez, T; Han, K; V Hansen, E; M Heeger, K; L Helis, D; Z Huang, H; G Huang, R; Imbert, L; Johnston, J; Juillard, A; Karapetrov, G; Keppel, G; Khalife, H; V Kobychev, V; Kotila, J; G Kolomensky, Yu; Konovalov, S; Liu, Y; Loaiza, P; Ma, L; Madhukuttan, M; Mancarella, F; Mariam, R; Marini, L; Marnieros, S; Martinez, M; H Maruyama, R; Mauri, B; Mayer, D; Mei, Y; Milana, S; Misiak, D; Napolitano, T; Nastasi, M; F Navick, X; Nikkel, J; Nipoti, R; Nisi, S; Nones, C; B Norman, E; Novosad, V; Nutini, I; O???donnell, T; Olivieri, E; Oriol, C; L Ouellet, J; Pagan, S; Pagliarone, C; Pagnanini, L; Pari, P; Pattavina, L; Paul, B; Pavan, M; Peng, H; Pessina, G; Pettinacci, V; Pira, C; Pirro, S; V Poda, D; Polakovic, T; G Polischuk, O; Pozzi, S; Previtali, E; Puiu, A; Quitadamo, S; Ressa, A; Rizzoli, R; Rosenfeld, C; Rusconi, C; Sanglard, V; Scarpaci, J; Schmidt, B; Sharma, V; Shlegel, V; Singh, V; Sisti, M; Speller, D; T Surukuchi, P; Taffarello, L; Tellier, O; Tomei, C; I Tretyak, V; Tsymbaliuk, A; Velazquez, M; J Vetter, K; L Wagaarachchi, S; Wang, G; Wang, L; Welliver, B; Wilson, J; Wilson, K; A Winslow, L; Xue, M; Yan, L; Yang, J; Yefremenko, V; Yumatov, V; M Zarytskyy, M; Zhang, J; Zolotarova, A; Zucchelli, S

doi:10.1088/1742-6596/2156/1/012233

In the past few years, attention has been drawn to the fact that a precision analysis of two-neutrino double beta decay (2νββ) allows the study of interesting physics cases like the emission of Majoron bosons and possible Lorentz symmetry violation. These processes modify the summed-energy distribution of the two electrons emitted in 2νββ. CUPID is a next-generation experiment aiming to exploit 100Mo-enriched scintillating Li2MoO4 crystals, operating as cryogenic calorimeters. Given the relatively fast half-life of 100Mo 2νββ and the large exposure that can be reached by CUPID, we expect to measure with very high precision the 100Mo 2νββ spectrum shape, reaching great sensitivities in the search for distortions induced by the physics beyond the Standard Model. In this contribution, we present the CUPID exclusion sensitivity for such New Physics processes, as well as the preliminary projected background of CUPID.