M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Investigating Neutrinoless Double Beta Decay

Status of the GERDA ExperimentMichael Altmann

Max-Planck-Institut für Physik, Munich

Physics

Concept

Exp. Setup

R&D DetectorsSchedule, etc.Summary

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Physics Motivation : Nature of the Neutrino

Neutrino masses and lepton flavour mixing established by oscillation experiments

Neutrino mass differences known

Still Unknown: absolute mass values

hierarchy scheme

= anti- ?

Neutrinoless Double Beta Decay

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Physics Goals and Experimental Requirements

For excluding inverted hierarchy:Sensitivity on 10 meV level required ton-scale @ B < 10-4 / keV kg yr

Phase 1

Phase 2

Phase-3

GE

RD

A S

en

sitiv

ity

Klapdor-Kleingrothaus positive evidence

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

GERDA: Germanium Detector Array

Array of HP-Germanium Diodes, made from isotopically enriched (86% in Ge-76) material

Phase-1:Use existing diodes from Heidelberg-Moscow and IGEX ( 15kg)0.01 / keV kg yr intrinsic background expectedGoal: verify concept; probe Klapdor-Kleingrothaus‘ evidence (if no event observed, 1 yr of measuring time needed to disprove at 98% cl)

Phase-2:Increase mass by adding 20 kg of new enriched Ge-detectorsGoal: 100 kg yr statistics at background level B<10-3 / keV kg yr

T1/2 > 2 * 1026 yr meff < 0.09 – 0.29 eV

Phase-3:(Depending on results of phase-2 and possibly other experiments)worldwide collaboration for really big experiment; close contacts and MoU with MAJORANA established

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

GERDA‘s Experimental Concept Assumption: External background is

dominant• Minimize all impure materials close to Ge diodes• Operate Ge diodes in ultraclean environment cryogenic liquid shield (LN or LAr); graded shielding

• Reject remaining background (internal and external) by exploiting different interaction topology (single-site multi-site; PSA)

Goal: Background index of 0.001 cts / (keV kg y) at Q=2039 keV

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

GERDA Location: Gran Sasso National Laboratory (LNGS)

GERDA1400 m ~ 3.800 m.w.e

Assigned Location for Phases 1 & 2: LNGS Hall A, next to the CRESST and LVD Experiments

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Experimental Setup at LNGS

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

GERDA‘s Cleanroom Facility at LNGS: LArGe

HD-Moscow‘s KI-detectors were handed over to GERDA

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

LArGe‘s Liquid Argon Test Stand

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Detector Arrangement

Modular Detector Arrangement :- Detector strings

- Hexagonal string arrangement

- Low mass, low background crystal holders and suspension- Additional strings can „easily“ be added when new detectors become available, with the vessel remaining cold

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Detector Suspension for Phase-1

- Low mass (bgd index < 10-2 / keV kg y )

- Use only screened materials with known radioimpurities (Cu, PTFE, Si)- Specific ORTEC-type contact (bottom of bore hole)- Mount and test every crystal individually (LArGe Facility at LNGS)

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Ge-76 Procurement for Phase-2

- Enrichment of 37.5 kg of Germanium ongoing (ECP, Krasnoyarsk, Russia)

- Delivery procedure tested with natGe: very smooth, no problems encountered (20 day trip Krasnoyarsk Munich, special shielding container: 10-20 attenuation factor for cosmogenic production of 68Ge and 60Co)- ongoing R&D: maintaining original purity during enrichment

optimizing yield of chemical purification to 6N metal

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Phase-2: Segmented DetectorsInteraction topology of -signal and -

background different anticoincidence for bgd suppression„pointlike“, single-site vs. „extended“, multi-site

60Co: 2 photons (=O(cm))

(multiple) Compton-scattering

2 electrons deposit energy locally (d = O(1 mm))

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Detector Development for Phase-2R&D on two types of detectors: p-type and n-type

n-type prototypes: Naked crystal: available & operated in LN Naked crystal, 6x3z segmented, true coax: on orderp-type prototypes:

Naked crystal, true coax: available & operated in LN

Naked crystal, true coax, 6x 1z segmented: available Naked crystal, true coax,

6x 3z segmented: on order

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Detector Suspension for Phase-218-fold segemented

detectors (true-coaxial, 3x6, n-type)

Kapton cable

bonded contacts

Total of 30g mounting material / detector

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Simulation Results on Segmented Detectors

- Monte Carlo (MaGe: common Majorana-Gerda simulation framework) : Anticoincidence between segments (18-fold segmentation)

factor 10 increase in 60Co rejection

- Further improvement (up to factor 5):Analysis of pulse shapes and mirror charges (PSA)( regain signal sitting on segment boundary)( 0.2 cm spatial resolution)

- R&D ongoing: Monte Carlo studies and PSA development Laboratory measurements with prototype

detectors

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Pulse Shape SimulationFull simulation of true coaxial 6-fold segmented detector (only 1 segment hit):

electrode electrode electrode

electrode electrode electrode

core

Cha

rge

Time

Hit segment:full energy deposit

Core signal: full energy deposit

Neighbouring segments:mirror charges

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Full Simulation of a True-Coax 18-fold Segmented Detector

Signals seen by the segment electrodes Position Reconstruction ( and z)

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Simulation Results on Segmented Detectors

PSA Information on radius and angle:

Clear correlation between time of charge collection and radius of interaction point

Correlation between ratio of amplitudes of neighbouring segments and angle of interaction point

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Status & Time Schedule2004:• Feb Letter of Intent to LNGS (hep-ex/0404039)• Sep Formation of Collaboration• Oct Funding request approved by MPG; Proposal to LNGS (wwwgerda.mppmu.mpg.de)

2005:• Feb GERDA approved by LNGS• Mar Technical proposal to LNGS; 30 kg of enriched Ge-76 for phase-2 ordered• May Funding requests approved by INFN• Jun Funding request approved by BMBF• Jul Ge-76 order enlarged to 37.5 kg; safety study for cryostat submitted to LNGS• Aug Expect decision by LNGS on system safety• Sep if OK: tendering for water tank, first orders for cryostat

2006:• Jun Start of water tank installation at LNGS• ??? Installation of cryostat, clean room and lock, muon veto, ...

2007:• spring Commissioning, then start of physics run

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

The GERDA Collaboration

M.Altmann, GERDA Status Report SNOLAB Workshop IV, 15.-17.8.2005

Summary and Conclusions

Approved by LNGS with location in hall A

substantially funded by BMBF,MPG, INFN and Russia (in kind) construction at LNGS start 6/06

in parallel: substantial R&D for and preparation of phase II start of data taking in 2007

phase-1: verify concept, probe KK-evidence for 0phase-2: T1/2 > 2 * 1026 yr m

eff < 0.09 – 0.29 eV phase-3: t.b.d., depending on results; ton-scale experiment in worldwide collaboration