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Low Background Counting. A Facility Wish List for the New Underground Laboratory F. Calaprice. Low Background Experiments. Dark Matter Searches Double Beta Decay Solar neutrinos Other Radioactivity dating Nuclear inspections. Typical Background Problems. Cosmic ray muons
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Low Background Counting A Facility Wish List for the New Underground Laboratory F. Calaprice Henderson Dusel Capstone Meeting
Low Background Experiments • Dark Matter Searches • Double Beta Decay • Solar neutrinos • Other • Radioactivity dating • Nuclear inspections Henderson Dusel Capstone Meeting
Typical Background Problems • Cosmic ray muons • Muon-induced neutrons & radioactivity • Radon & A=210 Pb-Bi-Po daughters • Atmospheric radioactive rare gas atoms • 222Rn & daughters; 39Ar, 85Kr. • Gamma and neutron emission from materials • Radon emanation from materials Henderson Dusel Capstone Meeting
What would we like to have? • Gamma detectors with sensitivity of < 1Bq/kg • Alpha & beta detectors for surface radioactivity • 210Pb, 210Po, etc. • 39Ar, 85Kr detectors for gasses • 222Rn emanation detectors • Low-radon fabrication clean room • High purity water • De-ionized and stripped of 222Rn, 39Ar, 85Kr. • High purity nitrogen (low 222Rn, 39Ar, 85Kr) • Facilities for precision cleaning • Hot high-purity detergents, acids, rinse water (much!) Henderson Dusel Capstone Meeting
IGe Gamma Detectors • Ge Max Planck Institute Heidelberg • GeMPI-1 1997 • 2.2 kg Ge-crystal • Materials in its construction carefully scanned for -rays • Radon suppression with air lock for inserting samples • Sealed chamber with N2 overpressure • Large samples (~15 liter) • Used to select materials for Borexino and Gerda • 238U (12Bq/kg); 232Th (4Bq/kg); 40K (31Bq/kg) • GeMPI-2 installed in LNGS- lower backgrounds Henderson Dusel Capstone Meeting
Borexino CTF as -Detector • Liquid scintillator in water tank • Liq.Scint:Highest purity material known (~nBq/kg) • Energy resolution adequate for gamma spectroscopy. • High detection efficiency 4 • Small sample (~2-10 liters) • Sensitivity: 238U, 232Th: ~1 Bq/kg, or better • Current Ge detectors limited to ~10 Bq/kg Henderson Dusel Capstone Meeting
Gamma Sensitivity of CTF Henderson Dusel Capstone Meeting
Detection of Radioactive Rare Gasses in CTF: 39Ar • 39Ar is produced by cosmic rays in the atmosphere: ~ 1 mBq/kg (Ar) • 39Ar is used for dating water/ice (t1/2= 260 y • ensitivity is limited by backgrounds • Direct counting has been used on gas samples • Direct counting is limited to ~1/10 atmospheric • Accelerator mass spectrometry has been developed at ANL. • Detection is limited to ~ 1/10 the atmospheric Henderson Dusel Capstone Meeting
Sensitivity of CTF to 39Ar • Rare gasses have high solubility in liquid scintillator: ~ 1% by mass. • I000 kg of liquid scintillator would have 10 kg of argon dissolved in it. • Count rate would be ~ 10 mBq. • CTF background is ~ 10 Bq/ton • Extend dating to 10 half-lives: ~ 2000 yr. Henderson Dusel Capstone Meeting
Argon in oceans and lakes • Ocean and lake water in contact with the atmosphere has ~ 0.5 atm-cc argon dissolved in one liter of water. • Disintegration rate/liter of water: 0.075 c/d • Currently, argon is removed from > 1000 liters of water by stripping. Typical count rater per sample is 75 c/d. • In small scintillator sample with < 1c/d background an improvement of current methods by x10 should be “easy”. Henderson Dusel Capstone Meeting
Summary • Low background counting will be crucial for upcoming experiments. • This is especially true for double beta decay experiments if other background suppression methods such as Ba detection in EXO do not work. • Current gamma detector technology can be used but development of more sensitive detectors is essential. • Dedicated space for new detectors such as CTF should be planned. • Big resources needed. This is not a simple job. Henderson Dusel Capstone Meeting