1 / 12

GERDA: GERmanium Detector Array Searching for 0 2 decay

GERDA: GERmanium Detector Array Searching for 0 2 decay. Xiang Liu Max-Planck-Institut f ü r Physik. 0 2 introduction GERDA setup & detectors 3. Low background & high sensitivity R&D Conclusion. SNOW 2006, May 2-6 th , 2006. 2 2 decay: (A,Z)  (A,Z+2) +2e+ 2 

brooks
Télécharger la présentation

GERDA: GERmanium Detector Array Searching for 0 2 decay

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. GERDA: GERmanium Detector Array Searching for 02 decay Xiang Liu Max-Planck-Institut für Physik • 02 introduction • GERDA setup • & detectors • 3. Low background • & high sensitivity • R&D • Conclusion SNOW 2006, May 2-6th, 2006

  2. 22 decay: (A,Z)  (A,Z+2) +2e+ 2 allowed by SM & exists. • 02 decay: (A,Z)  (A,Z+2) +2e if s Majorana & have mass. L=2 • Many isotopes can be used to search for 02. • Best limit from Heidelberg-Moscow experiment (HdMo) with 76Ge. Neutrino mixing & 02 decay Open questions: • Absolute mass scale? • Normal hierarchy or inversed? • Nature: Dirac or Majorana?  02 decay might address all. SNOW2006 Page 2

  3. Search 02 & measure T1/2 Phase I Phase II m (eV) Lightest neutrino mass (eV) G0: phase space integral M0: nuclear matrix element <m>=  Vei2 mi (Vei: neutrino mixing matrix) GERDA Phase I: Existing detectors Phase II: new detectors Future: 1 ton experiment Effective Majorana neutrino mass: m SNOW2006 Page 3

  4. GERDA new features: • Ge detectors directly submerged in LN2/LAr (as cooling & shielding) • Segmented Ge detectors (phase-II) Ge detector array LN2/LAr cryostat Water tank GERDA Setup • 02 rare process • Large amount of target mass • High efficiency detecting signal • Low background 76Ge 8% in nature,need enrichment (reduce bg) Detector = source, >95% signal effi. Excellent  (FWHM ~2 keV at 1.3 MeV), high Q value (2.04 MeV) existing detectors & experiences from HdMo & IGEX. LNGS Hall A (3800 m.w.e.) Clean room & Lock Scintillator veto (top of clean room) Čerenkov veto (PMTs in water tank) SNOW2006 Page 4

  5. (Phase II) readout cable holder HV cable suspension strings Detectors & supports Materials near detectors: as little as possible, as pure as possible. Phase-I: HdMo & IGEX detectors, sum ~15kg, non-segmented Phase-II:New detectors, sum ~25kg, 18 segments (3z6) SNOW2006 Page 5

  6. Status of Existing Phase-I Detectors • IGEX detectors testedinside Vacuum storage Can. FWHM 2.2 - 2.3keV at 1332keV • HdMo detectors stored at LNGS, all tested. • One HdMo detector taken out from Vacuum Can for testing. HdMo Setup ANG1 Ge crystal HdMo claim Signal: 28.75  6.86 events Bg level: 0.11 cts/[keV kg year] If claim true, Phase-I will have Signal: ~13 events Bg level: <0.01 cts/[keV kg year] <3 events in 10keV window at Q value. SNOW2006 Page 6

  7. Status of Phase-II Detectors • 37.5kg Ge, 87.25% 76Ge, purity >99.9% (in GeO2) enriched in Russia, transported to MPI Munich on April 3rd 2006, now stored underground (200m.w.e) • Next steps: purification, crystal pulling & detector fabrication. SNOW2006 Page 2

  8. High sensitivity = Low background a) b) Phase II Phase I a) Assessment of uncertainties in QRPA 02-decay nuclear matrix elements V.A. Rodin, A. Faessler, F. Simkovic, P. Vogel [Nucl-th 0503063] b) Search for Neutrinoless Double Beta Decay with Enriched 76Ge in Gran Sasso 1990-2003, H.V. Klapdor-Kleingrothaus, I.V. Krivosheina, A. Dietz and O. Chkvorets, Phys. Lett. B586 (2004) 198-212 SNOW2006 Page 8

  9. Use segments to reject background 02 signal: 2 electrons deposit energy very localized (<1mm) Background : Mostly Compton scattering 2~3 cm mean free path (mostly multi-segment) SNOW2006 Page 9

  10. MC simulation of bg. Water tank • MC package (MaGe) for both Gerda & Majorana. • Upper limit on contamination levels for all materials calculated. • Bg. Index calculated with available materials. Cryo vessel (Phase II) SNOW2006 Page 10

  11. 6-segment p-type detector in LN2. Co60 R&D: Ge detector properties Several test facilities being built with detectors directly in LN2/LAr. • Both n & p-type Ge cycled multi times in LN2 & LAr Similar behavior in LN2/LAr. No deterioration of performance. • One 18-segment n-type detector is under study. SNOW2006 Page 11

  12. Conclusion • Open questions in  : absolute mass? hierarchy? Majorana or Dirac? • 02might answer all these questions. • GERDA searches for 02decay in 76Ge. • Ge detectors are submerged directly in LN2/LAr (cooling & shielding). • IGEX & HdMo detectors for Phase-I. • Segmented Ge detectors for Phase-II. • Goal for bg. rate: 10-3 cts/[keV kg year] (Phase-II), difficult but feasible. • With this bg. rate, sensitivity of 0.2eV on m expected. • Several test facilities for GERDA are being built. • Both n- & p-type detectors cycled in LN2/LAr without obvious deterioration. • Once the GERDA concept is proven, global experiment with 1t Ge might be pursued (MoU with Majorana exists). SNOW2006 Page 12

More Related