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Spherical TPC development and trends I. Giomataris, December 2008 TPC - Paris

Spherical TPC development and trends I. Giomataris, December 2008 TPC - Paris. Collaboration S. Andriamonje, S. Aune, E. Bougamont, M. Chapelier, P. Colas, J. Derré, E. Ferrer, G. Gerbier, I. Giomataris, M. Gros, P. Mangier, X.F. Navick CEA-Saclay ,

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Spherical TPC development and trends I. Giomataris, December 2008 TPC - Paris

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  1. Spherical TPC development and trends I. Giomataris, December 2008 TPC - Paris Collaboration S. Andriamonje, S. Aune, E. Bougamont, M. Chapelier, P. Colas, J. Derré, E. Ferrer, G. Gerbier, I. Giomataris, M. Gros, P. Mangier, X.F. Navick CEA-Saclay, I. Savvidis et al., University of Thessaloniki P. Piquemal, M. Zampalo, LSM S. Gaffet, P. Salin, LSBB I. Irastorza, University of Saragoza J. D. Vergados, University of Ioannina I. Giomataris

  2. Idea of a spherical detector Low energy neutrino search I. Giomataris, J.D. Vergados,Nucl.Instrum.Meth.A530:330-358,2004, • Large Spherical TPC 10 m radius • 200 MCi tritium source in the center • Neutrinos oscillate inside detector volume L23=13 m • Objectives • Measure q13 (systematic free) • Neutrino magnetic moment studies<< 10-12B • Measurement of the Weinberg angle at low energy Challenge : detect electron recoils down to T=100 eV (Tmax=1.27 eV) Low background level (to be measured and subtracted) Measure the radial depth of the interaction I. Giomataris

  3. Room size oscillations Seen by a 150 m TPC Seen by the spherical NOSTOS TPC I. Giomataris

  4. A Novel large-volume Spherical Detector with Proportional Amplification read-out, I. Giomataris et al. Jul 2008. 12pp, e-Print: arXiv:0807.2802 [physics.ins-det] Radial TPC with spherical proportional counter read-out • 5.9 keV 55Fe signal • Very low electronic noise: low threshold • Good fit to theoretical curve including avalanche induction and electronics C= Rin= 7.5 mm < .1pF E=A/R2 20 s 15 mm • Simple and cheap • single read-out • Robustness • Good energy resolution • Low energy threshold • Efficient fiducial cut I. Giomataris

  5. Electrostatics deal How to keep radial field Ideal solution: field 1/R2 degrador around the wire No field corrector With field corrector I. Giomataris

  6. A simple electrostatic solution I. Savvidis idea New idea by I. Giomataris and I. Irastorza, combines also second voltage corrector: “umbrella field corrector”, big improvement in stability I. Giomataris

  7. Early experimental results S. Aune et al., AIP Conf.Proc.785:110-118,2005. I. Giomataris et al.,Nucl.Phys.Proc.Suppl.150:208-213,2006. I. Giomataris and J. D . Vergados, AIP Conf.Proc.847:140-146,2006 Ar + 2% Isobutane • Stability: • tested up to ~3 months. • No circulation of gas. Detector working in sealed mode. (1 pass through an oxysorb filter) • No absorption observed • Signal integrity preserved after 60 cm drift. • Not high E needed to achieve high gain. I. Giomataris

  8. Signal dispersion with depthto estimate distance of interaction Better than 10 cm accuracy Very efficient for applying ficducial cut Remove backgrounds Average time dispersion of 5.9 keV deconvoluted events VS.Distance drifted Ar+CO2 P=0.25 bar Depth (cm) I. Giomataris

  9. Study neutrino-nucleus coherent elastic scattering s ≈N2E 2, D. Z. Freedman, Phys. Rev.D,9(1389)1974 JI Collar, Y Giomataris - Nuclear Inst. and Methods in Physics Research, A, 2001 H. T. Wong, arXiv:0803.0033-2008 PS Barbeau, JI Collar, O Tench - Arxiv preprint nucl-ex/0701012, 2007 Nuclear reactor measurement sensitivity with present prototype • At 10 m from the reactor, after 1 year run (2x107s), assuming full detector efficiency: • Xe (s ≈ 2.16x10-40 cm2), 2.2x106neutrinos detected, Emax=146 eV • Ar (s ≈ 1.7x10-41 cm2), 9x104neutrinos detected, Emax=480 eV • Ne (s ≈ 7.8x10-42 cm2), 1.87x104neutrinos detected, Emax=960 eV • Challenge : Very low energy threshold • We need to calculate and measure the quenching factor • Application : Remote control of nuclear reactors • Background must be kept as low as possible I. Giomataris

  10. How to get simple and cheap Supernova counter Neutrino-nucleus coherent elastic scattering Supernova neutrino detection with a 4 m spherical detector Y. Giomataris, J. D. Vergados, Phys.Lett.B634:23-29,2006 For En = 10 MeV s ≈N2E 2 ≈ 2.5x10-39 cm2,Tmax = 1.500 keV For En = 25 MeV s ≈ 1.5x10-38 cm2,Tmax = 9 keV Expected signal : 100 events (Xenon at p=10 bar) per galactic explosion Idea : A European or world wide network of several (tenths or hundreds) of such dedicated Supernova detectors robust, low cost, simple (one channel) To be managed by an international scientific consortium and operated by students Required background level reasonable Extra galactic sensitivity could be reached e - e , 1 0.1 10 s I. Giomataris

  11. At higher energy (MeV): Excellent energy resolution measured Radon gas emission spectrum with spherical detector RMS = .5% 222Rn 218Po 214Po Energy resolution under amplification: a world record !! Strong point of the new concept I. Giomataris

  12. Neutron energy and flux measurement 3He + n 1H + 3H (Q= 765 keV) Results at ground Saclay Ar-CH4(98-2)+80mg He3 10Po peak .13 cps !! .03 cps I. Giomataris

  13. In 2008 Detector installed in LSM laboratory goal: measure thermal neutron background and estimate fast neutron flux with 10 gr 3He I. Giomataris

  14. 3 g of 3He have been introduced on June 30 Detector is stable operating in seal mode Gas Ar +2% CH4 at p=280 mbar 210Po 760 keV 5 weeks 210Po 760 keV 218Po 214Po I. Giomataris

  15. Amplitude Rise time (ms) Thermal neutron peak after rise time cut Great background rejection !!! Efficiency of cut 60% Results in LSM Thermal neutron flux 3x10-6/cm2/s Goal: measure fast neutrons Benchmark result: Massive He-3 detector, Excellent background level Thermal neutrons 760 keV I. Giomataris

  16. Applications: • Fast neutron measurement at underground lab • Neutron seasonal variations • Correlations with sun spot activity • Home land security • neutrino detection through neutron production • anti-neutrino(e) + p ---> e+ + n • Nuclear reactor monitoring • Cheap SuperNova detector • Home land security

  17. Summary • A new spherical detector is born and developed • Good energy resolution, robust and stable • Many applications in low energy neutrino physics are open • Large volume -massive high-sensitivity neutron detector • Low energy neutrino physics, Nuclear reactor control, SuperNova detection • Double beta decay through Xe-136 ? • Advantage: Good energy resolution with large volume detector done • Excellent background rejection through fiducial cuts done • But poor tracking accuracy to be studied I. Giomataris

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