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Premium member Presentation Transcript LArTPC: Large Liquid Argon TPC for the NuMI Off-axis Beam: LArTPC: Large Liquid Argon TPC for the NuMI Off-axis Beam Brief description of some of the efforts of the LArTPC group which is pushing the development of large liquid argon TPC’s aimed at upcoming neutrino experiments as well as experiments in a neutrino factory era. Greg Bock FNAL/BNL Meeting November 14, 2005 (Almost entirely a selection of slides from Dave Finley’s presentation to the ISS) Slide2: Electrons compared to 0's at 1.5 GeV in LAr TPC Multiple secondary tracks pointing back to the same primary vertex Each track is two electrons – 2 mip scale per hit Electrons Single track (mip scale) starting from a single vertex Dot indicates hit, color is collected charge green=1 mip, red=2 mips (or more) use both topology and dE/dx to identify interactions cm cm cm cm X plane zoom in X plane zoom in U plane zoom in U plane zoom in The promise of liquid argonSlide3: Aim is to produce a viable design for a 15 kt - 50 kt liquid argon detector. Basic concept follows ICARUS: TPC, drift ionization electrons to 3 sets of wires (2 induction, 1 collection) record signals on all wires with continuous waveform digitizing electronics Differences aimed at making a multi-kton detector feasible; Construction of detector tank using industrial LNG tank as basic structure Long(er) signal wires Single device (not modular) Basic parameters: Drift distance - 3 meters; Drift field - 500 V/cm (gives vdrift = 1.5 m/ms) Wire planes - 3 (+/-300 and vertical); wire spacing 5 mm; plane spacing 5 mm Number of signal channels ~ 100,000 (15kt), 220,000 (50kt) LRadiation = 14 cm, dE/dx = 2.1 MeV/cm, 55,000 electrons/cm liberated The Large Liquid Argon TPCLArTPC’s report to NuSAG: LArTPC’s report to NuSAG Fermilab Note: FN-0776-E A Large Liquid Argon Time Projection Chamber for Long-baseline, Off-Axis Neutrino Oscillation Physics with the NuMI Beam Submission to NuSAG September 15, 2005 D. Finley, D. Jensen, H. Jostlein, A. Marchionni, S. Pordes, P. A. Rapidis Fermi National Accelerator Laboratory, Batavia, Illinois C. Bromberg Michigan State University C. Lu, K. T. McDonald Princeton University H. Gallagher, A. Mann, J. Schneps Tufts University D. Cline, F. Sergiampietri, H. Wang University of California at Los Angeles A. Curioni, B. T. Fleming Yale University S. Menary York University Contact Persons: B. T. Fleming and P. A. RapidisNuMI Liquid Argon TPC Overview : NuMI Liquid Argon TPC Overview Note: At this point in time … “15” could be “50” “1” could be “3” etcSlide6: Some Specific challenges: Argon: (long drift) purification - starting from atmosphere (cannot evacuate detector tank) - effect of tank walls & non-clean-room assembly process Wire-planes: long wires - mechanical robustness, tensioning, assembly, breakage/failure Signal processing: electronics - noise due to long wire and connection cables (large capacitance) surface detector - data-rates, - automated cosmic ray rejection - automated event recognition and reconstruction (and there are others for example, High Voltage) The Large Liquid Argon TPCSlide7: Many large LNG tanks in service. excellent safety record Detector Tank based on Industrial Liquefied Natural Gas (LNG) storage tanksSlide8: 3D `Model’ cutaway 15 kt detector H V S i g n a l Changes from standard LNG tank: inner tank wall thickness increased - LAr is 2 x density of LNG; trusses in inner tank to take load of the wires: penetrations for signals from inner tank to floor supported from roof of outer tank; Tank diameter ~ 26meters The Large Liquid Argon TPC: SketchDevelopment tasks: Development tasks Engineering Development to demonstrate scalability to large tank Construction of tank with the same techniques to be used with the large tank Demonstrate argon purity with the same techniques to be used with the large tank Mechanical integrity of TPC Readout signal / noise Microphonics due to argon flow Uncover whatever surprises there may be Physics development using existing technology Record complete neutrino interactions (nm and ne) in a high intensity beam Establish physics collaboration by: Developing event identification Developing reconstruction Developing analysis Establish successful technology transferElectron Neutrinos in MINOS Surface Building: Electron Neutrinos in MINOS Surface Building NuMI is presently providing ~2E20 POT per year. The 130 ton LArTPC has a 50 ton fiducial mass. Thus … the LArTPC detector would get ~1600 ne events / year.Slide11: setup for lifetime measurements (effect of materials and effectiveness of different filters) under assembly at Fermilab. Materials Tests Slide12: LArTPC Test Setup at Yale Purity and light collection Purity monitor in liquid argonSlide13: Support at Fermilab -few physicists and engineers, beginning some technical set ups. Growing support from University groups in smaller technical setups, software efforts, etc Receiving support for technology transfer from experts in Europe, and hoping to learn more from ongoing tests Continuing along the path to develop Large Liquid Argon TPCs - not only in the ongoing NuMI era, but also into the neutrino factory era, and for other physics The group would like to develop wider collaboration. Most Fermilab people are also starting to think about what can be learned with the INFN groups. A workshop in Italy in February or March seems like it will happen and it could help establish a way to begin to sort out who does what. Figuring out what makes sense on coordinating with US labs has only just now begun. Final Comments You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
BNLTRIP LArTPC Bock UpBeat Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 26 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: November 08, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript LArTPC: Large Liquid Argon TPC for the NuMI Off-axis Beam: LArTPC: Large Liquid Argon TPC for the NuMI Off-axis Beam Brief description of some of the efforts of the LArTPC group which is pushing the development of large liquid argon TPC’s aimed at upcoming neutrino experiments as well as experiments in a neutrino factory era. Greg Bock FNAL/BNL Meeting November 14, 2005 (Almost entirely a selection of slides from Dave Finley’s presentation to the ISS) Slide2: Electrons compared to 0's at 1.5 GeV in LAr TPC Multiple secondary tracks pointing back to the same primary vertex Each track is two electrons – 2 mip scale per hit Electrons Single track (mip scale) starting from a single vertex Dot indicates hit, color is collected charge green=1 mip, red=2 mips (or more) use both topology and dE/dx to identify interactions cm cm cm cm X plane zoom in X plane zoom in U plane zoom in U plane zoom in The promise of liquid argonSlide3: Aim is to produce a viable design for a 15 kt - 50 kt liquid argon detector. Basic concept follows ICARUS: TPC, drift ionization electrons to 3 sets of wires (2 induction, 1 collection) record signals on all wires with continuous waveform digitizing electronics Differences aimed at making a multi-kton detector feasible; Construction of detector tank using industrial LNG tank as basic structure Long(er) signal wires Single device (not modular) Basic parameters: Drift distance - 3 meters; Drift field - 500 V/cm (gives vdrift = 1.5 m/ms) Wire planes - 3 (+/-300 and vertical); wire spacing 5 mm; plane spacing 5 mm Number of signal channels ~ 100,000 (15kt), 220,000 (50kt) LRadiation = 14 cm, dE/dx = 2.1 MeV/cm, 55,000 electrons/cm liberated The Large Liquid Argon TPCLArTPC’s report to NuSAG: LArTPC’s report to NuSAG Fermilab Note: FN-0776-E A Large Liquid Argon Time Projection Chamber for Long-baseline, Off-Axis Neutrino Oscillation Physics with the NuMI Beam Submission to NuSAG September 15, 2005 D. Finley, D. Jensen, H. Jostlein, A. Marchionni, S. Pordes, P. A. Rapidis Fermi National Accelerator Laboratory, Batavia, Illinois C. Bromberg Michigan State University C. Lu, K. T. McDonald Princeton University H. Gallagher, A. Mann, J. Schneps Tufts University D. Cline, F. Sergiampietri, H. Wang University of California at Los Angeles A. Curioni, B. T. Fleming Yale University S. Menary York University Contact Persons: B. T. Fleming and P. A. RapidisNuMI Liquid Argon TPC Overview : NuMI Liquid Argon TPC Overview Note: At this point in time … “15” could be “50” “1” could be “3” etcSlide6: Some Specific challenges: Argon: (long drift) purification - starting from atmosphere (cannot evacuate detector tank) - effect of tank walls & non-clean-room assembly process Wire-planes: long wires - mechanical robustness, tensioning, assembly, breakage/failure Signal processing: electronics - noise due to long wire and connection cables (large capacitance) surface detector - data-rates, - automated cosmic ray rejection - automated event recognition and reconstruction (and there are others for example, High Voltage) The Large Liquid Argon TPCSlide7: Many large LNG tanks in service. excellent safety record Detector Tank based on Industrial Liquefied Natural Gas (LNG) storage tanksSlide8: 3D `Model’ cutaway 15 kt detector H V S i g n a l Changes from standard LNG tank: inner tank wall thickness increased - LAr is 2 x density of LNG; trusses in inner tank to take load of the wires: penetrations for signals from inner tank to floor supported from roof of outer tank; Tank diameter ~ 26meters The Large Liquid Argon TPC: SketchDevelopment tasks: Development tasks Engineering Development to demonstrate scalability to large tank Construction of tank with the same techniques to be used with the large tank Demonstrate argon purity with the same techniques to be used with the large tank Mechanical integrity of TPC Readout signal / noise Microphonics due to argon flow Uncover whatever surprises there may be Physics development using existing technology Record complete neutrino interactions (nm and ne) in a high intensity beam Establish physics collaboration by: Developing event identification Developing reconstruction Developing analysis Establish successful technology transferElectron Neutrinos in MINOS Surface Building: Electron Neutrinos in MINOS Surface Building NuMI is presently providing ~2E20 POT per year. The 130 ton LArTPC has a 50 ton fiducial mass. Thus … the LArTPC detector would get ~1600 ne events / year.Slide11: setup for lifetime measurements (effect of materials and effectiveness of different filters) under assembly at Fermilab. Materials Tests Slide12: LArTPC Test Setup at Yale Purity and light collection Purity monitor in liquid argonSlide13: Support at Fermilab -few physicists and engineers, beginning some technical set ups. Growing support from University groups in smaller technical setups, software efforts, etc Receiving support for technology transfer from experts in Europe, and hoping to learn more from ongoing tests Continuing along the path to develop Large Liquid Argon TPCs - not only in the ongoing NuMI era, but also into the neutrino factory era, and for other physics The group would like to develop wider collaboration. Most Fermilab people are also starting to think about what can be learned with the INFN groups. A workshop in Italy in February or March seems like it will happen and it could help establish a way to begin to sort out who does what. Figuring out what makes sense on coordinating with US labs has only just now begun. Final Comments