Background issues for the Cryogenic Dark Matter Search

1. Background issues for the Cryogenic Dark Matter Search Laura Baudis Stanford University

2. The Cryogenic Dark Matter Search • phonon and ionization detectors to measure WMP-nucleus elastic scattering • current location: SUF ~ 16 mwe • future location: Soudan ~ 2000 mwe • Run21: 1 tower (4 Ge, 2 Si) • Soudan: total of 6 towers (7 kg Ge, 2 kg Si)

3. CDMS detectors • measure phonons and ionization • discrimination between nuclear • and electron recoils • nuclear recoils: WIMPs, n • electron recoils: g,e,a • ionization yield Y=ionization/recoil energy • dependent on type of recoil • electron recoil Y=1 • nuclear recoil Y=1/3 > 99.8% gamma rejection external gamma source external neutron source phonon trigger threshold

4. Electron contamination! 

5. CDMS background goals CDMS background goals SUF: 1 event/ kg d or 0.01 events/kg d keV Soudan: factor 100 improvement 0.01 events/kg d = 1 event/100 kg d

6. Background sources Muon induced background internal neutrons: n -> muon capture and low energy photo-nuclear reactions in Cu cryostat and inner Pb shield: 100/kg d (Cu), 243/kg d (Pb) (veto coincident) external neutrons: n produced by muon interactions outside the veto (veto-anticoincident) Intrinsic radioactivity of materials Ambient gamma and neutron background

7. A c t i v e M u o n V e t o Detectors Pb Shield Polyethylene Inner Pb shield Layout of the CDMS I shield • plastic scintill. • 15 cm Pb • 25 cm PE • HPCu-cryostat • 1cm inner Pb

8. Electromagnetic background • muon coincident: 60 events/kg d keV • muon anticoincident: 2 events/kg d keV • (veto efficiency > 99.9 %: => < 0.1 events/kg d keV) • residuals: non-muon induced! • radioactivity of materials surrounding the crystals single scatter photon background: 0.5 ev/kg d keV with 99.9% rejection efficiency=> 0.0005 ev/kg d keV (SUF goal: 0.01 ev/kg d keV) surface electron background: 0.3 ev/kg d keV rejection efficiency > 95% (ZIPs 99.7%!) => 0.015 ev/kg d keV

9. ZIP Risetime Cut trise>31 s neutrons gammas neutrons trise<31 s betas 60 keV betas

10. Neutrons from Rock Ice Box, concentric Cu cans, outer radius 30 cm • HE m-nuclear interactions => HE n • n with E > 50 MeV penetrate PE shield and produce LE sec. n • ( < 20 MeV) => NR < 100 keV • rate from literature has x4 uncertainty for 17 m.w.e. • MC simulations of m-induced hadron cascades yields n-rate x3 higher than observed veto-anticoincident NR: • due to vetoing of associated m and hadrons (~ 40% rejection from n)? n Cold Stem ~1 kg Ge Detectors 30 cm Poly Shield 15 cm Pb Shield 5 cm Plastic Scintillator Dimensions give approximate radial thickness of layers

11. External neutron background • absolute flux: difficult to predict! • can be measured: • compare NR rates in Si and Ge • rate of multiple scatters gives a direct • measurement of n background • (WIMPs scatter only once!)

12. CDMS uses Si and Ge detectors • WIMPs: Ge has ~6x higher interaction rate per kg than Si • Neutrons: Si has ~2x higher interaction rate per kg thanGe • Breaks the final degeneracy in particle discrimination! neutrons WIMPS 40 GeV

13. Data from 1998 and 1999 Data Runs • 1999: 4x165g Ge BLIP (10.6 kg d) • 13 single scatter nuclear recoils (1.2/kg/day) • 4 multiple scatter nuclear recoils (0.4/kg/day) 1998 100 g Si ZIP (1.6 kg days) 4 single scatter nuclear recoils (2.5/kg/day) all single-scatters nuclear recoil candidates Analysis threshold (10 keV) 90% acceptance

14. + Data w/ 68% confidence interval Prediction based on Ge mult, Si Predictions based on most likely Nuclear Recoil Events  1 4 3.4  13 16 Comparison with with MC • Ge multiples and Si singles imply large expected neutron • background with large statistical uncertainty

15. Typical background spectra @ SUF Nuclear recoil efficiency

16. CDMS II Soudan • muon flux reduced x 104! • 7 towers each with 3 Ge & 3 Si ZIP detectors • Total mass of Ge = 7 X 3 X 0.25 kg > 5 kg • Total mass of Si = 7 X 3 X 0.10 kg > 2 kg

17. CDMS II background goals factor 3 factor 15 factor 4 x 104 ~ 25 events expected for 7 kg yr exposure

18. Is this achievable? Gammas: 99.5 % discr. eff. assumed (99.9 % reached) understand residual background Betas: 95% discr. eff. assumed (99.7 % for ZIPs) avoid surface contaminations Neutrons:mflux reduced by factor 104 @ Soudan internal: 99 % eff. muon veto sufficient external: 1/3 of total expected background (MC) (25 events for ~ 7 kg yr exposure) better MC needed

19. MC simulations with FLUKA • standalone FLUKA (http://fluka.web.cern.ch/fluka): • most complete treatment of physical processes at • high AND low energies (but not very user friendly...) • simulate muon propagation + hadron shower generation • in tunnel; save HE neutrons entering the tunnel and • transport them in GEANT and/or in FLUKA • later requires complete geometry in FLUKA, doable with • help of ALIFE (http://AliSoft.cern.ch/offline/fluka/ALIFE.html) • better estimation of absolute n-flux • correlations between n-hits and veto response

20. What other backgrounds do we fear? • cosmogenics • surface contaminations (Rn-plateout)

21. Cosmogenics Activation of Si/Ge crystals and other materials during production and transportation at the Earth‘s surface A precise calculation requires: cosmic ray spectrum (varies with geomagnetic latitude) cross sections for the production of isotopes Problem: cross sections! only few measured production is dominated by (n,x) reactions: 95% (p,x) reactions: 5% Existing programs use: semiempirical formulas based on data to calculate cross sections: COSMO (Martoff et al.) SIGMA (J. Bockholt et al.)

22. Cosmogenics in Ge 30 d exposure at see level, 1 year storage below ground COSMO SIGMA

23. Important for CDMS realistic exposure: 4 months above ground estimations from Run 19 3H: 1.34 x COSMO 68Ge: 1.26 x COSMO CDMS goal for gammas: 95 /kg yr keV 3H: 1.34 x 50 -> not a problem ! 68Ge: 1.26 x 2.5 x 103 !

24. Cosmogenics in Si Martoff, Science87 Modif. Cosmo 3 months at see level, 1 yr below ground 3H: 47 ev/kg yr keV for ~ 4 month exposure; not a problem!

25. 3H production already in the right order of magnitude • avoid any further activation • store Ge/Si crystals and Cu in tunnel C @ SUF • transport detectors via ground: 10 h of flight ~ 125 d exposure! • install PE shield box at SNF (fabrication site): • 10 cm of PE reduce n-flux by factor of 30! However...

26. The Radon problem 222Rn -> 210Pb source: 238U chain noble gas colorless tasteless odorless plateout: adhesion of Rn daughters on surfaces 1 Bq ~ 5 x 105 Rn atoms air: 40/10 Bq/m3 (in/out)

27. Radon plateout the long lived 210Pb accumulates on surfaces and decays: b-: Emax = 63 keV: most dangereous -> surface electrons amount of 210Pb on surfaces depends on: - exposure time: t - Rn concentration in air: A - efficiency 222Rn (air) -> 210Pb (surface): p goal for CDMS II: 10-4/cm2 keV d scrubbing + low p + low t!

28. Radon Scrubbing Facility @ Stanford • use for cleaning and assembly of ZIP detectors and towers inner room < class 100 foyer wetbench antiroom

30. Radon Scrubbing Facility continuous particulate + Rn monitoring particulates: better than class 100 Rn: ~ 6 Bq/m3 but scrubbing not started yet! goal: factor 10 better

31. Conclusions • CDMS I • background goal (1 ev/kg d) reached @ SUF • sensitivity @ SUF limited by external n-background • CDMS II • ZIP technology: 99.9 % discrimination of bulk e-recoils • 99.7 % discrimination of surface e • still have to keep track of possible background sources! • reach 100 times better sensitivity ~1 event / 100 kg d

32. Non-Neighbor interaction B3 B4 B5 Neighbor interaction B6 Neutron Multiple Scatters in Ge BLIPs • Observe 4 neutron multiple scatters in • 10-100 keV multiple events • 3 neighbors, 1 non-neighbor • Calibration indicates negligible contamination by electron multiples Neighbors Non-Neighbors surface electrons photons photons Ionization Yield B5,6 Ionization Yield B6 neutron neutrons Ionization Yield B4,5 Ionization Yield B4