Neutrino Physics and Dark Matter Physics with Ultra-Low-Energy Germanium Detector

1. Lin, Shin-Ted/ 林欣德 On Behalf of Taiwan Experiment On NeutrinO (TEXONO) Collaboration Institute of Physics, Academia Sinica / @ 5th Italian-Sino Workshop on Relativistic Astrophysics Neutrino Physics and Dark Matter Physics with Ultra-Low-Energy Germanium Detector • Overview of TEXONO Collaboration • Kuo-Sheng Reactor Neutrino Laboratory • Results on Neutrino Magnetic Moments & status on Neutrino-Electron Elastic Scattering • Physics & Requirements for ULE-HPGe • R&D projects on ULE-HPGe Prototypes • Plans

2. TEXONO Collaboration Collaboration : Taiwan(AS, INER, KSNPS, NTU) ; China(IHEP, CIAE, THU, NJU) ; Turkey(METU) ;India(BHU) Close Partnership with :Korea (KIMS) Program: Low Energy Neutrino & Astroparticle Physics • Kuo-Sheng (KS) Reactor Neutrino Laboratory • oscillation expts.  mn0  anomalousnproperties & interactions • reactor : high flux of low energy electron anti-neutrinos • nphysics full of surprises , need intensen-source • study/constraint new regime wherever experimentally accessible • explore possible new detection channels

3. Kuo-Sheng Nuclear Power Plant KS NPS-II : 2 cores  2.9 GW KS nLab: 28 m from core#1

4. Kuo Sheng Reactor Neutrino Laboratory Front View (cosmic veto, shielding, control room …..) Inner Target Volume n/fission 235U: 3.4 238U: 0.5 239Pu: 1.8 241Pu: 0.4 U (n,g) 1.2 Configuration: Modest yet Unique Flexible Design: Allows different detectors conf. for different physics

5. Reactor Neutrino Spectrum Reactor Operation Data n/fission 235U:3.4 238U:0.5239Pu:1.8 241Pu:0.4 U (n,g) 1.2 F(ne) ~ 6.4X1012 / sec*cm2

6. Reactor Neutrino Interaction Cross-Sections quality Detector requirements mass Under Analysis • SM s(ne) • T > 3 MeV • R&D : • Coh. (nN) • T < 1 keV Results: • mn(ne) • T ~ 1-100 keV

7. KS Experiment: Period I, II, III,IV,V-I Detectors CsI(Tl) Array ULB-HPGe [1 kg] FADC Readout [16 ch., 20 MHz, 8 bit] Multi-Disks Array [few Tb*6]

8. fundamental neutrino properties & interaction ; necessary consequences of neutrino masses/ mixings Astrophysics bound on mn ~ (10-10 – 10-12mB) however, model dependence Anomalous n-e scattering is valid for - both Dirac/Majorana n - both Diagonal/Transition mij Neutrino Electromagnetic Properties : Magnetic Moments Minimally Extended Standard Model: However, many models can enhance it significantly (nM, WR …..)

9. Magnetic Moment Searches @ KS • n-e scattering with mn • simple compact all-solid design : HPGe (mass 1 kg) enclosed by activeNaI/CsI anti-Compton, further by passive shielding&cosmic veto • selection: single-event after cosmic-veto, anti-Comp., PSD

10. +/- +/- 2 Data Analysis • TEXONO data • background comparable to underground CDM experiment : ~ 1 day-1keV-1kg-1 (cpd) • DAQ threshold 5 keV analysis threshold 12 keV • Combined all information i / f Before/After cuts i / f F Spectrum ; Reactor On/Off n SM + m = = Fe (SM) + ke Fe (mn) n

11. Systematic effects Best-fit Results on neutrino magnetic moment • The limit based on 570.7/127.8 days of Reactor ON/OFF: mn(ne) <7.4 X 10-11mB (90% CL) @ PRD 75 2007

12. Neutrino radiative decay • Search of mn at low threshold • high signal rate & robustness: Gemma prelim. Result: mn(ne) <5.4 X 10-11mB(90% CL) @hep-ex0705.4576v1

13. nee scattering SM MM However, SM >>MM at few MeV ! The differential cross section can be represented

14. Single Crystal QL Vs QR (Raw Data) Z = 0 cm 208Tl 40K 137Cs Region of Interest for SMs(ne) CsI(Tl) Array (~200 kg): s(ne) Data analysis under way .. (~40000/~12000 day-kg for ON/OFF in PII to PV) Z =40 cm

15. Status of neutrino-electron scattering Background understanding and suppression --Multiple-hit analysis (Cosmic ray tagged, gcascades of 208Th ) =>s(sin2qw) = 28 % • more data • Global analysis of all spectra Expect:

16. “Ultra-Low-Energy” HPGe Detectors • ULEGe – developed for soft X-rays detection ; easy & inexpensive & robust operation • Prototypes built and studied : • 5 g @ Y2L • 4 X 5 g @ KS/Y2L • 10 g @ AS/CIAE • Segmented 180 g @ KS • PC-500 g single element @AS • Physics for O[100 eV threhold1 kg mass1 cpd detector]: • nN coherent scattering • Low-mass WIMP searches • Improve sensitivities on mn [ mnsearch  ~10-11mB ] • Implications on reactor operation monitoring • Open new detector window & detection channel available for surprises

17. ULEGe-Prototype built & being studied : 5 g 10 g 4 X 5 g Segmented 180 g with dual readout

18. Neutrino-Nucleus Coherent Scattering A fundamental neutrino interaction never been experimentally-observed • s  ~N2applicable at En<50 MeV ( Take Q.F. =0.25, S/N >1 at 250 eV of threshold; At threshold 100 eV-> 11 count /day/ kg) • a sensitive test to Standard Model • an important interaction/energy loss channel in astrophysics media • a promising new detection channel for neutrinos, relative compact detectors possible (implications to reactor monitoring) • involves new energy range at low energy, many experimental challenges & much room to look for scientific surprises

19. Characteristics of WIMP signal • Scattering off nuclei • A2 dependence • coherence loss • relative rates • MW relative to MN • large MW- lose mass sensitivity • if ~100 GeV • Present limits on rate • WIMP mass if not too heavy • different targets • accelerator measurements • galactic origin • annual modulation • directional courtesy of Gaitskell Vary MW for MN=73 from Jungman et al. dR/dER recoil energy, ER (keV)

20. Sensitivity Plot for CDM-WIMP direct search • Low (<10 GeV) WIMP Mass / Sub-keV Recoil Energy : • Not favored by the most-explored specific models on galactic-bound SUSY-neutralinos as CDM ; still allowed by generic SUSY • Solar-system bound WIMPs require lower recoil energy detection • Other candidates favoring low recoils exist: e.g. non-pointlike SUSY Q-balls. • Less explored experimentally

21. Yang-Yang Underground Laboratory • Operated by KIMS Collaboration, 700 m of rock overburden in east Korea • flagship program on CsI(Tl) for CDM searches • TEXONO  Install 5 g ULB-ULEGe at Y2L ; Study background and feasibility for CDM searches ; may evolve into a full-scale O(1 kg) CDM experiment Y2L

22. Evaluation of Selection Efficiency: • Select clean sample ofphysicsevents with cosmic-ray and anti-Compton tags • Study survival probabilities of these with the independent selection cuts on Ge-signals • Good efficiency > 200 eV for low background KS data with 4X5 g

23. Sub-keV Background Measurements & Comparisons 1 kg 5 g 4 X 5 g • Similar background at KS & Y2L for same detector • Apparent difference between 5 g & 1 kg at T> 5 keV due to scaling with surface area instead, reproduced in simulations • Best Background with 4X5 g comparable to CRESST-1 after corrections due to quenching factor • Intensive studies on background understanding under way

24. Results on WIMP Spin-Independent Cross Section Limits & Sensitivities Standard conventional analysis – Maximum gap method ; Optimal Interval method

25. WIMP Spin-dependent Cross Section Limits & Sensitivities Allowed regions of WIMP-nucleon couplings (proton and neutron) with a WIMP mass of 5 GeVc^-2, at 90%C.L WIMP-neutron cross section

26. Backgrounds: cosmic rays and natural radioactivity WIMP scatters (< 1 evts /10 kg/ day) swamped by backgrounds ( > 106 evts/kg-d) Radioactive Nuclides in solids, surroundings 238U, 232Th chains, 40K Cosmic Rays Fast muons Radioactive Nuclides in atmosphere Airborne Radioactivity222Rn Radioactive Nuclides in detector, shield (especially 222Rn daughters, including 210Pb t1/2=22 years) Slow muons Shield contaminants Neutron capture (α, n) Electrons Muon capture Photo fission Spontaneous fission Gammas (α, n) Neutrons courtesy of S. Kamat

27. R&D Program towards Realistic O(1 kg) Size Experiments (bothnN& CDM) : • measure & study background at sub-keV range at KS & Y2L ; design of active & passive shielding based on this. • compare performance and devise event-ID (PSD & coincidence) strategies of various prototypes • devise calibration & efficiency evaluation schemes applicable to sub-keV range • measure quenching factor of Ge with neutron beam • study scale-up options ULEGe-detector • Keep other detector options open

28. Single Readout Event ID– correlate two channels with different gains & shaping times e.g. 4 X 5 g Sampling of Specific Range for non-trigger-Channel 2 – i.e. look for +ve fluctuations at specific and known times Energy as defined by trigger-Channel 1 Noise Signal Ch #1 : Ch #2 :

29. Dual Readout Event ID– correlate anode/cathodes in amplitude & timing e.g. Peak Position Correlations between Electrodes Seg. 180 g Noise Signal Cathode : Anode :

30. Quenching Factor Measurement for Ge at CIAE’s Neutron Facilities: With 13 MV Tandem • Goals for 2008 Runs : • Use actual ULEGe 100-eV detector • Use lower energy neutron beam with a smaller tandem

31. p S1 S0 Detector Scale-up Plans: Most of energy deposited in the surface. A larger detector have a better g suppression . • 500-g, single-element, modified coaxial HPGe design, inspired by successful demonstration of Chicago group (nucl-ex/0701012) • Dual-electrode readout and ULB specification • Arrived in April 2008 @AS.

32. Summary & Outlook • An O[100 eV threshold1 kg mass1 cpd detector] has interesting applications in neutrino and dark matter physics, also in reactor monitoring • Open new detector window & detection channel : potentials for surprise • Mass Scale-Up: recent demonstration of realistic design • Threshold– ~300 eV at hardware level, intensive studies on software techniques to aim at ~100 eV, & on their stabilities and universalities • Prototype data at reactor already provide competitive sensitivities for WIMP search at mass<10 GeV . • Sub-keV Background understanding and suppression – under intensive studies