SNOLAB and EXO

1. SNOLAB and EXO David Sinclair SNOLAB Workshop August 2005

2. EXO • Search for double beta decay using Xe • Identify decay energy by ion detection • Control background by tagging events with Ba daughter • 200 kg separated isotope liquid Xe prototype under construction – will be installed at WIPP

3. Canadian participation in EXO • Carleton/Laurentian groups • 7 Canadian faculty • First R&D funding in April • Role clarified in July collaboration meeting

4. Xe offers a qualitatively new tool against background: 136Xe 136Ba++ e- e- final state can be identified using optical spectroscopy (M.Moe PRC44 (1991) 931) Ba+ system best studied (Neuhauser, Hohenstatt, Toshek, Dehmelt 1980) Very specific signature “shelving” Single ions can be detected from a photon rate of 107/s 2P1/2 650nm 493nm 4D3/2 • Important additional • constraint • Huge background • reduction metastable 80s 2S1/2

5. Possible Gas Version • Gas counter would allow tracking • Better rejection of gamma backgrounds • Single site criteria • Two Bragg peak criteria • Possibly better energy resolution • Better prospects for in situ Ba tagging

6. Liquid Advantages • Smaller active volume • Easier shielding • No high pressure containment • Canadian groups will develop Gas Option

7. Objectives • To demonstrate a feasible concept for a gas phase Xe detector for bb decay • If successful, to build a 200 kg prototype • If really successful, expand to tonne scale

8. Possible concept for a gas double beta counter Anode Pads Micro-megas WLS Bar Electrode Blue/red laser ->->->->->->->->->->->->->->->->->->->-> Wire cathode WLS Bars For 200 kg, 10 bar, box is 1.5 m on a side

9. Issues – Energy Resolution • Need to demonstrate ~1% or better • What gain mechanism to use? • Micromegas? • What gas additives to use? • Quench gas? • Drift velocity? • WLS for 178 nm light? • Loss of 178 nm light? • TMAE or other to convert light to electrons? • What is the optimal pressure?

10. Issues - Tracking • Want to identify decay vertex • Want to see 2 Bragg peaks • Want to reject multi-site events • Eventually want to look and angular correlation

11. Issues – Ba tagging • Need to demonstrate a robust Ba tagging scheme • Demonstrate Ba+ livetime • Demonstrate Ba++ -> Ba+ conversion • Measure Ba tagging efficiency • Demonstrate low false tagging probability

12. Engineering • Much larger volume suggests water shielding to get purity • Look at thin gas containment, high pressure water, use cavern to contain pressure

13. Programme – Energy Resolution • Explore TPC energy resolution in Xe w/wo optical detection – Carleton/Laurentian/Neuchatel+Saclay? • Optimize micromegas • Explore gas mixtures • Explore scintillation detection

14. Programme - Tracking • Carleton • Initially need MC study • Look at impact of magnetic fields

15. Programme – Ba Tagging • Carleton/Laurentian/Colorado • Ba line widths • Ba lifetime • Tagging schemes • Demonstrate reliable, in-situ tagging • Study backgrounds • Note – Line widths -> high laser power, need selective detection • Toy Model – Pulse blue laser, look for blue light when laser off, use fluorecene (peak absorption 490 nm, emission 520 nm, 97% Quantum yield, 80,000 /mol/cm absorption) + bialkali PMT

16. Programme • Do studies of energy resolution in small test cell at Carleton (~1 year) • Do MC studies and optimize tracking (~1 year) • Develop laser lab for Barium counting at SNOLAB • Build ~30 cm test chamber to operate underground at SNOLAB to demonstrate full concepts including trigger, tracking, tagging (use 134Cs to simulate decay) • Develop 200 kg prototype to be ready in ~3 years when liquid prototype tests complete at WIPP

17. Schedule • Aim to have a concept in 1 year • 1% energy resolution • Demonstrated tagging • Conceptual design for vessels, shielding • Demonstrate concepts with 30 cm chamber in 2 years • Start construction of 200 kg detector in cavern capable of expansion to tonne scale in 3 years