Presentation is loading. Please wait.

Presentation is loading. Please wait.

Shower Containment and the Size of a Test Calorimeter Adam Para, September 6, 2006.

Published byDamon Lane Modified over 9 years ago

Similar presentations

Presentation on theme: "Shower Containment and the Size of a Test Calorimeter Adam Para, September 6, 2006."— Presentation transcript:

1 Shower Containment and the Size of a Test Calorimeter Adam Para, September 6, 2006

2 Why Test Calorimeter??? It is not yet proven, but it is quite plausible that a dual readout calorimeter may offer very good energy resolution for jets  simulation and analysis It is plausible that high enough light collection efficiency can be attained for Lead Glass + fiber, or Lead Glass + APD configuration  optical test laboratory It is plausible that cheap enough Lead Glass (or other Cherenkov radiator) can be produced  vendors contacts It is plausible that a realistic mechanical design of a large hermetic calorimeter can be produced  engineering studies We need to demonstrate the energy resolution, linearity and e/  response in the test beam

3 How Big a Test Calorimeter? Hadron calorimeters are large (m 3 ), hence expensive. Can’t afford to be bigger than necessary. (if we build it) we want to demonstrate good energy resolution ~(20-30)%/sqrt(E), that is ~2-3% energy resolution at 100 GeV. If the calorimeter is not long/wide enough there will be some energy leakage from the calorimeter and its fluctuations will contribute to the energy resolution. Need containment ~98% or better.

4 How Long a Calorimeter Need 2.5-3 m long lead glass Blue = Cherenkov Red = ionization

5 How Wide a Calorimeter? Need ~ 1m wide test module Red = ionization Blue = Cherenkov

6 Available Building Blocks E70 experiment (Lederman, upsilon): SF5 lead glass blocks 6”x6”x16” 6” is far too thick. Optimal absorber thickness needs study (sampling fluctuations): 3” (thick)? 2”(thin)? Options 3 m = 120”: 40 thick planes 60 thin planes 7 x 6” = 105 cm wide 32”+12” = 110 cm tall 18 ‘pixels’ per plane Fundamental unit: lead glass + scintillator plate Transverse segmentation: Common LG and scintillator Is 6”x16” sufficient?

7 Readout? Assume: LG block and the scintillator plates are read out via a single waveshifting fiber (light collection efficiency and uniformity to be demonstrated) Channel count: 18 x 2 x 40 (60) = 1440 (2160) Assume Hamamatsu 5800-M64 phototube (?)  need 25(35) tubes Electronics? DAQ?

8 Cutting the Lead Glass Blocks Cut along the long axis: Diamond band saw Water-jet (with abrasives) Initial vendor contacts: promising Surface quality: do cut surfaces need to be polished (manpower = cost) Need to find out what the surface quality is Need to find out what is the acceptable surface quality

Download ppt "Shower Containment and the Size of a Test Calorimeter Adam Para, September 6, 2006."

Similar presentations

High Resolution Hadron Calorimetry with Dual Readout Adam Para, Fermilab Trends in Photon Detectors, Trieste, June 3, 2008.

High Resolution Hadron Calorimetry with Dual Readout Adam Para, Fermilab Trends in Photon Detectors, Trieste, June 3, 2008.
Quartz Plate Calorimeter Prototype Ugur Akgun The University of Iowa APS April 2006 Meeting Dallas, Texas.

Quartz Plate Calorimeter Prototype Ugur Akgun The University of Iowa APS April 2006 Meeting Dallas, Texas.
Jin Huang Los Alamos National Lab.  Cited from March collaboration Meeting EC group Internal Communication Jin Huang 2 Preshower ID power drop significantly.

Jin Huang Los Alamos National Lab.  Cited from March collaboration Meeting EC group Internal Communication Jin Huang 2 Preshower ID power drop significantly.
SoLID EC Design for IHEP 2012/10. Basic Features of Preliminary Design Based on COMPASS Shashlyk module design. 0.5mm lead/0.12mm air gap/1.5mm scintillator/0.12mm.

SoLID EC Design for IHEP 2012/10. Basic Features of Preliminary Design Based on COMPASS Shashlyk module design. 0.5mm lead/0.12mm air gap/1.5mm scintillator/0.12mm.
W. Clarida, HCAL Meeting, Fermilab Oct. 06 Quartz Plate Calorimeter Prototype Geant4 Simulation Progress W. Clarida The University of Iowa.

W. Clarida, HCAL Meeting, Fermilab Oct. 06 Quartz Plate Calorimeter Prototype Geant4 Simulation Progress W. Clarida The University of Iowa.
Testbeam Requirements for LC Calorimetry S. R. Magill for the Calorimetry Working Group Physics/Detector Goals for LC Calorimetry E-flow implications for.

Testbeam Requirements for LC Calorimetry S. R. Magill for the Calorimetry Working Group Physics/Detector Goals for LC Calorimetry E-flow implications for.
Fiberless Coupled Tiles for a High Granularity Scintillator-SiPM Calorimeter Rick Salcido Northern Illinois University November 14, 2009 Prairie Section.

Fiberless Coupled Tiles for a High Granularity Scintillator-SiPM Calorimeter Rick Salcido Northern Illinois University November 14, 2009 Prairie Section.
Off-axis Simulations Peter Litchfield, Minnesota  What has been simulated?  Will the experiment work?  Can we choose a technology based on simulations?

Off-axis Simulations Peter Litchfield, Minnesota  What has been simulated?  Will the experiment work?  Can we choose a technology based on simulations?
Could CKOV1 become RICH? 1. Characteristics of Cherenkov light at low momenta (180 < p < 280 MeV/c) 2. Layout and characterization of the neutron beam.

Could CKOV1 become RICH? 1. Characteristics of Cherenkov light at low momenta (180 < p < 280 MeV/c) 2. Layout and characterization of the neutron beam.
How to Build a Neutrino Oscillations Detector - Why MINOS is like it is! Alfons Weber March 2005.

How to Build a Neutrino Oscillations Detector - Why MINOS is like it is! Alfons Weber March 2005.
Doug Michael Jan. 12, 2004. First goal is to be ready to select an optimal technology in ~one year. –Demonstrate that fundamental technologies are ready.

Doug Michael Jan. 12, First goal is to be ready to select an optimal technology in ~one year. –Demonstrate that fundamental technologies are ready.
The Tagger Microscope Richard Jones, University of Connecticut Hall D Tagger - Photon Beamline ReviewJan. 23-24, 2005, Newport News presented by GlueX.

The Tagger Microscope Richard Jones, University of Connecticut Hall D Tagger - Photon Beamline ReviewJan , 2005, Newport News presented by GlueX.
1 Tianchi Zhao University of Washington Concept of an Active Absorber Calorimeter A Summary of LCRD 2006 Proposal A Calorimeter Based on Scintillator and.

1 Tianchi Zhao University of Washington Concept of an Active Absorber Calorimeter A Summary of LCRD 2006 Proposal A Calorimeter Based on Scintillator and.
Study of a Compensating Calorimeter for a e + e - Linear Collider at Very High Energy 30 Aprile 2007 Vito Di Benedetto.

Study of a Compensating Calorimeter for a e + e - Linear Collider at Very High Energy 30 Aprile 2007 Vito Di Benedetto.
C.Woody BNL sPHENIX EMCAL Conceptual Design sPHENIX Design Study Meeting September 7, 2011.

C.Woody BNL sPHENIX EMCAL Conceptual Design sPHENIX Design Study Meeting September 7, 2011.
Heavy Scitillating Crystals and Glasses for a Combined EM and HCal at ILC Tianchi Zhao University of Washigton Sept. 25, 2007.

Heavy Scitillating Crystals and Glasses for a Combined EM and HCal at ILC Tianchi Zhao University of Washigton Sept. 25, 2007.
Status of EIC Calorimeter R&D at BNL EIC Detector R&D Committee Meeting January 13, 2014 S.Boose, J.Haggerty, E.Kistenev, E,Mannel, S.Stoll, C.Woody PHENIX.

Status of EIC Calorimeter R&D at BNL EIC Detector R&D Committee Meeting January 13, 2014 S.Boose, J.Haggerty, E.Kistenev, E,Mannel, S.Stoll, C.Woody PHENIX.
The Design of Barrel Electromagnetic Calorimeter (BEMC) October 13 2001 ---Lu Jun-guang.

The Design of Barrel Electromagnetic Calorimeter (BEMC) October Lu Jun-guang.
Adam Para, Fermilab, April 26, 2010 1 Total Absorption Dual Readout Calorimetry R&D Fermilab, Caltech, University of Iowa, Argonne National Laboratory,

Adam Para, Fermilab, April 26, Total Absorption Dual Readout Calorimetry R&D Fermilab, Caltech, University of Iowa, Argonne National Laboratory,
Cost of a Large Solid Scintillator Detector Jeff Nelson Fermilab.

Cost of a Large Solid Scintillator Detector Jeff Nelson Fermilab.

Similar presentations

Ads by Google