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CUORE first phase: CUORE-0

CUORE first phase: CUORE-0. 1 CUORE-like tower of 13 planes - 4 crystals each 52 TeO 2 5x5x5 cm 3 crystals (750 g each) Detector Mass : 39 kg TeO 2 130 Te mass (natural i.a.): 11 kg of 130 Te. All detector components manufactured, cleaned and stored with protocols defined for CUORE

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CUORE first phase: CUORE-0

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  1. CUORE first phase: CUORE-0 1 CUORE-like towerof 13 planes - 4 crystals each 52 TeO25x5x5 cm3 crystals (750 g each) Detector Mass: 39 kg TeO2 130Te mass (natural i.a.):11 kg of 130Te • All detector components manufactured, cleaned and stored with protocols defined for CUORE • Assembled with the same procedures foreseen for CUORE • In the 25 years-old CUORICINO cryostat GOALS: • Proof of Concept for CUORE in all stages • Test and debug the CUORE assembly line (thermistor gluing, signal wires bonding, tower assembly) • Test of the CUORE DAQ and analysis framework • Extend the physics reach beyond CUORICINO while CUORE is being assembled • Demonstrate potential for DM and Axion detection

  2. Sensitivity to 0nbb [*] C. Arnaboldi et al., Phys. Rev. C 78, 035502 (2008) ε = 87.4% (Monte Carlo calculation) i.a. (130Te) = 34.2 % (ICP-MS Measurement)

  3. Sensitivity to 0nbb and to DM Dark Matter Sensitivity limited by background due to cryostat contaminations CUORE0 2 y CUORE 5 y T1/2 sensitivity = 5.9 x 1024 y (90% CL) <mee> < (204 ÷ 533) meV ( [*]) b = 0.05 c/keV/kg/y, T = 2 y 0nbb 90% C.L. sensitivity to the cross-section for spin independent interactions normalized to nucleon [*] PSF from Kotila and Iachello, PRC 85 (2012) 034316 NME from Poves et al., NPA 818 (2009) 139; Faessler et al., JoP G: Nucl. Part. Phys. 39 (2012) 124006; Fang et al. , PRC 83 (2011) 034320; Suhonen et al., JoP G: Nucl. Part. Phys. 39 (2012) 124005; Iachello et al., PRC 87 (2013) 014315; P.K. Rath et al., Phys. Rev. C82 064310 (2010); T. R. Rodriguez et al., Phys. Rev. Lett 105 252503 (2010)

  4. Assembly procedure CUORE-0 assembly was performed in the new CUORE clean room following all the stages and using all the equipment developed for CUORE

  5. Thermistor gluing The gluing of CUORE-0 thermistor to crystalswas performed with the new CUORE gluing semi-automatic machine (in a N2 flushed glove box): fast, operator independent, minimizes radioactive contaminations, makes this stage more reproducible thus improving detector uniformity.

  6. Tower assembly The assembly of the tower was done with the CTAL (CUORE Tower Assembly Line)provided of a sealed and flushed stainless steel chamber (Garage) supporting a working plane where 4 different glove boxes switch allowing 4 operations to be performed (mounting, bonding, cabling and tower storage) with radioactivity control and reproducible protocols

  7. Signal wires connection The signal readout is provided by gold wires directly bonded on the assembled tower in a N2 fluxed glove box. The bonding proceeds in 3 main steps: 1. ball bonding on a Au pad on the thermistor; 2. bonding of the wire on Au balls on a Cu pad; 3. reinforcing. 0 Wire Bonding on Au balls on Cu pad + reinforcing Wire Bonding on Au pad on thermistor

  8. Shield installation and transportation After shield installation the tower has been closed in a flushed Plexiglas box, then moved to the special opening door of the CUORE clean room with a trans-pallet. It has then been lifted with a fork-lift to the CUORICINO clean room where it has been joined to the cryostat dilution unit (operations not necessary for CUORE).

  9. CUORE-0 status • CUORE-0 was cooled down to a base T ~ 8 mK to start the pre-operation and optimization phase in August 2012 • Pre-operation was disturbed by2 vacuum leaks (the cryostat is ~25 years old) which deteriorated detector performances • We were ableto perform calibrations despite the leaks, showing reasonable detector performance • The second leak has been fixed at the beginning of February • We plan to restart soon the pre-operation and optimization phase

  10. Detector performance Ch. # 45 pulse in calibration 2615 keV  from 208Tl -decay Ch. # 45 calibration spectrum (232Th source) E (@2615 keV) = 5.3 keV (FWHM) • Successfully tested and defined the CUORE assembly procedures • Demonstrated that a complete CUORE tower can be assembled in less than 4 weeks • 51 detectors alive (out of 52) 10

  11. Conclusions • First CUORE tower, CUORE-0, was successfully assembled using CUORE assembly tools and procedures • CUORE-0 demonstrated that one CUORE-like tower can be assembled in less than 4 weeks • 51 out of 52 detectors are alive • Best channels showed FWHM energy resolutions in the Region Of Interest E ~ 5 keV in calibration spectrum • The evaluated sensitivity after 2 years of livetime is T1/2 = 5.9 x 1024 y (90% CL)

  12. Back-up slides

  13. Sensitivity to 76Ge claim Significance level at which CUORE-0 can observe a 0 signal consistent with the claim in 76Ge [**], with b=0.05 c/keV/kg/y Spread due to the NMEs + the 1 error on the reported 76Ge measurement [**] H.V. Klapdor-Kleingrothaus et al., Mod. Phys. Lett. A 21 (2006) 1547

  14. Sensitivity to DM (1) The background rate at low energy (3-25 keV) of CUORE and CUORE0 was assumed equal to the one measured in a CCVR run in which a dedicated trigger algorithm was used to lower the threshold [*] (=3keV). [*] S. Di Domizio, F. Orio and M. Vignati, JINST 6 (2011) P02007 Energy region still under study

  15. Sensitivity to DM (2) In order to evaluated CUORE-0 and CUORE sensitivity to DM Toy Monte Carlo simulations were performed generating background events according to the fit of the measured distribution, and WIMP events according to the theoretical distribution described in [*], using a quenching factor for nuclear recoils in TeO2 equal to 1 [**]. The dependence of the WIMP interaction rate on the time in the year was included. As it can be seen from the plot in slide 3, CUORE could investigate the same parameter space of the DAMA/LIBRA experiment, and could be the only experiment other than DAMA/LIBRA looking for an annual modulation of dark matter interactions. [*] J. D. Lewin and P. F. Smithl, Astrop. Phys. 6 (1996), no. 1 87 [**] A. Alessandrello et. al., NIM.A 409 (May, 1998) 451

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