1. Gd Liquid scintillator: completion of the R&D! Stability 0,1 % Gd in PXE LENS R&D  new metal β-diketone molecule (MPIK) Stable: 0.1% Gd-Acac (few months) Baseline receipie ~80% mineral oil + ~20% PXE + Fluors + wavelenght shifters In-loaded scintillators (0.1 %, 5% loading) are counting @Gran Sasso Spare stable receipies available (MPIK, INFN/LNGS) Gd-Acac molecule Completion of the R&D first half of 2004 Choice of the final scintillator Stability & Material compatibility  Aging tests (MPIK, Saclay) 3+ Gd

2. Gd Liquid scintillator tests in Saclay Goal: 1/ Test the LONG term stability of the scintillator 2/ Test the material compatibility with acrylic, glue,...  Towards the desgin of the acrylic vessels Tight stainless steel boxes flushed with N 2 – 20- 130cl quartz cuvettes Aeging test  scintillator temperature ~50 degrees Systematic periodic photospectrometer absorbance measurements

3. Acrylic vessels 4m 2m 2.4m 3.6m 2.8m Gamma catcher Target Thickness = 6mm Final assembly (in several part) In Chooz’s site Assembly in the manufacturer workshop

4. Suspension: 3 points at 120 degrees Thickness: 6 mm Empty weight: –Target = 220kg –Gamma catcher = 470kg  Maximum stress: 12 MPa Stress in acrylic vessels DAPNIA/SIS/LCAP - JMB Target Gamma catcher

5. Filling of vessels: Dosing pums (diaphragm pumps or peristaltic pumps): accuracy ~1% Pump + electronic flowmeter: accuracy ~0.5% Weight & density measurements Density: accuracy 0.001 g/cm3 (can reach 0.0001 g/cm3) Weigth: accuracy <10 kg on ~12 tons. ->volume ~0.1%

6. Full detector simulation PCC & APC, Kurchatov

7. Parameters used for the simulation Reactor thermal power: 8.4 GW Near detector distance: 150 meters Volume N & F: 12.67 m 3 Far detector distance: 1050 meters with PXE => 12.5 tons Near detector efficiency: 32 % 50 % dead time x 80 % global load factor x 80 % detection Far detector efficiency: 64 % No dead time x 80 % global load factor x 80 % detection “Standard systematic errors”: absolute relativebackgrounds 1 par fit or with

8. Sensitivity at 90% C.L. if sin 2 (2  13 )=0 versus integrated luminosity in RNU σ abs =2% σ rel =0.6% σ shape =2% σ b2b =1% Reactor 1 (2 RNU)Reactor 2 (40 RNU) New target composition increases luminosity by 30 % 1 RNU = 200 t.GW.y

9. Support for the EDF power company to do a 2 nd experiment @CHOOZ Double-CHOOZ sensitivity: sin 2 (2  13 )<~0.03, 90% C.L. (  m 2 = 2.0 10 -3 eV 2 ) Current limint: CHOOZ : sin 2 (2  13 )<0.2  discovery potential ! Technology / design well known (CHOOZ, BOREXINO, KamLAND, …)  few R&D needed : Gd loading (stability) + material compatibility (Started, to be completed in half a year) Proto-collaboration: PCC, Saclay, APC, TUM, MPIK, Tubingen, Kurchatov, Italy (likely to grow during the winter)  (maxi-)letter of intent (February 2004)  final proposal (6 months) Experiment cost, Double-CHOOZ case: 2 x ~13 tons, preliminary detector cost <10 Meuros (Civil engineering not included) Our Goal @Double- CHOOZ: Construction starts end of 2005 Start data taking in 2007-2008 Summary & outlook @Double-CHOOZ 2003 200420052006200720082009 SiteData takingProp.Construction ?design < sin 2 (2  13 ) < ~0.04 < sin 2 (2  13 ) < 0.025-003 Far detector starts