1 / 8

Instrumentation for precise neutrino and neutron spectroscopy using trapped radioactive ions

Nicholas Scielzo Lawrence Fellow Physics Division, Physical Sciences. Instrumentation for precise neutrino and neutron spectroscopy using trapped radioactive ions August 8, 2009. Lawrence Livermore National Laboratory, P. O. Box 808, Livermore, CA 94551.

norman
Download Presentation

Instrumentation for precise neutrino and neutron spectroscopy using trapped radioactive ions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Nicholas Scielzo Lawrence Fellow Physics Division, Physical Sciences Instrumentation for precise neutrino and neutron spectroscopy using trapped radioactive ions August 8, 2009 Lawrence Livermore National Laboratory, P. O. Box 808, Livermore, CA 94551 This work performed under the auspices of the U.S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA27344 LLNL-PRES-408002

  2. Spectroscopy of “invisible” and difficult-to-detect particles Combine ion-trapping techniques with modern detector technology to perform beta-decay and beta-delayed neutron decay measurements with unprecedented precision • Entire decay kinematics reconstructed to determine energy/momenta of: • Neutrinos in beta decay • Neutrons in beta-delayed neutron emission • Ion traps • Efficiently collect any isotope nearly at rest, suspended only by electromagnetic fields • Recoil nucleus momentum available for study • <1mm3volume • Isotopically-pure samples can be prepared b n Neutrino escapes detection! b n n Neutron emission

  3. RFQ electrodes SIDE VIEW: inject ions trapped ions HPGe detector HPGe detector HPGe detector HPGe detector Si telescope END VIEW: Open-Geometry Ion Trap with Detector Array Storage times >50 sec DC Confinement DV ≈ 100 V RF Confinement Fission fragments 1000 Vpp at 700 kHz 8Li 1000 Vpp at 2000 kHz

  4. Si telescope HPGe detector HPGe detector HPGe detector HPGe detector fast scintillator fast scintillator Measure any correlation between emitted particles n bparticles conversion electrons MCP g rays a p g alpha particles protons b ion b-delayed neutrons recoil ions MCP

  5. 8Li b-n angular correlation 8Li  8Be* + b- + n Surround trapped-ion sample with position-sensitive detector system to precisely reconstruct momentum vectors of all emitted particles (including neutrino!) a + a Plastic scintillator DSSSD n Q ≈ 13 MeV t1/2 = 0.808 sec a 8Li+ • momentum/energy measured from double-sided silicon-strip detectors (DSSSD) and plastic-scintillator detector • 8Be recoil (up to 12 keV!) determined from a-particle break-up • energy difference up to 730 keV • angle deviation from 1800 by up to 70 q b a

  6. 8Li b decay detector requirements Double-sided silicon strip detector will not wash out the kinematic shifts – energy resolution of <100 keV and angular resolution of <20 a= +1 a = -1

  7. Beta-delayed neutron emission Beta-delayed neutron emission measurement takes advantage of 1 mm3 trapped-ion sample and sub-ns timing resolution of fast plastic scintillators and MCP detectors to precisely determine neutron momentum/energy from time-of-flight of recoiling daughter ion 95Rb  95Sr* + b- + n 94Sr* + n Q = 4.9 MeV t1/2 = 0.378 sec Pn ≈ 9% MCP ion detector Example of time-of-flight measurement to measure neutron energies and absolute branching ratios: Assume 1 MeV neutron emitted from 95Sr beta-decay daughter. Recoil energy of 94Sr is then 10 keV and time-of-flight to MCP detector at a distance of 10 cm is 700 ns. At this distance, resolution of neutron energy measurement from the time-of-flight is limited to ~1% by 1 mm3 trap volume. Intrinsic efficiency of MCP for keV-energy ions can be nearly 100%. At ANL, measurements can be performed on fission fragments from the CARIBU facility. n 94Sr Plastic scintillator 95Rb+ b n Plastic scintillator

  8. Main Requirements ATLAS Beams: • Low energy • High intensity CARIBU Beams: • Low energy • High intensity • High purity • Low emittance • Many neutron-rich isotopes Equipment: • Ion traps with long storage times, tight confinement, open geometry for detectors • Position-sensitive detectors and associated electronics • Adequate shielding to allow full use of beam intensity

More Related