1 / 12

Development of GEM Detectors for Muon Tomography

Development of GEM Detectors for Muon Tomography. N. Leioatts , T. Garlick , A. Moss, A. Quintero, M. Hohlmann Department of Physics and Space Sciences Florida Institute of Technology. Gas Electron Multiplier (GEM). Particle detector technique (1).

kimi
Download Presentation

Development of GEM Detectors for Muon Tomography

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. Development of GEM Detectors for Muon Tomography N. Leioatts, T. Garlick, A. Moss, A. Quintero, M. Hohlmann Department of Physics and Space Sciences Florida Institute of Technology

  2. Gas Electron Multiplier (GEM) • Particle detector technique (1). • Constructed of Kapton foil clad in copper on both sides, with holes through layers (1). • Voltage applied • High electric field in holes • Avalanche of ions and e- • e- collected (2). (1) Sauli, F.; NIM A386 531, 1997. (2) http://cerncourier.com/cws/article/cern/27921

  3. Our GEM • Triple GEM • Limit to Gain per foil (sparking) • 4 foils made • Planned Use: Homeland Security (Muon Tomography for detection of nuclear contraband. J. Helsby, et al. FAS 2008) • 70:30 Ar:CO2 • 55Fe Source for testing • Emits monoenergetic 5.9 KeV X-ray

  4. Our Detector • HV circuit • Readout Amplifier • Oscilloscope

  5. Construction • Arrive • Stretched • On Machined G10 Frames • Mounted • With Stycast • Cut • Assembled • On lid of detector

  6. Then It Works!! • Not so much • Large leakage current • Peak occurs much lower than GEM operating voltage (3) (3) F. Murtas. LNF-INFN. Frascati (2002)

  7. Areas that Needed Improvement • GEMs Sparking • Box Pressure • Gluing • Larger Clamps • Amplifier Readout

  8. Improvements • Gas Leakage • Sturdier Steel Frames • 8” C-clamps • Stycast • Soldered connector pins • Amplifiers • Characterized • differential to single side amplification Amplifier B, Tested with a Square input

  9. Electric Field Testing • Linear Output from HV circuit • Operating Voltage: • Vin ~ 9V • Produces 300V across a single foil

  10. Individual Testing • Motivation: High leakage current between foils • Systematic testing of each foil (4) • Current drops with time • As in a capacitor • Foil I shows a larger leakage current than Foils III and IV (4) Barbeau, P.S. et al. NIM A 515 (2003)

  11. Conclusions • Solved physical (gas) leakage problems • Still has electrical (current) leakage problems • Currently working on this

  12. Future • Continue individual testing until all foils are satisfactorily characterized • Reinstall Detector and continue to troubleshoot problems until detector works satisfactorily • Move to the construction of a larger detector

More Related