APS April2000 Meeting Ahmet Sedat Ayan Dept. of Physics & Astronomy University of Iowa.

Slides:

Advertisements

Similar presentations

Stefan Roesler SC-RP/CERN on behalf of the CERN-SLAC RP Collaboration

Advertisements

1 ALICE EMCal Electronics Outline: PHOS Electronics review Design Specifications –Why PHOS readout is suitable –Necessary differences from PHOS Shaping.

CMS Heavy Ion Physics Edwin Norbeck University of Iowa.

Quartz Plate Calorimeter Prototype Ugur Akgun The University of Iowa APS April 2006 Meeting Dallas, Texas.

for Fusion Power Monitoring

1 A DIRC for GlueX Paul Mueller Oak Ridge National Laboratory and Stefan Spanier University of Tennessee, Knoxville BaBar DIRC Collaboration for the GlueX.

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.

New & Old Calorimetry Technologies with New Tools for LC Y.Onel, University of Iowa D.R.Winn, Fairfield University ALCPG - Victoria Linear Collider Workshop.

The Tagger Microscope Richard Jones, University of Connecticut Hall D Tagger - Photon Beamline ReviewJan , 2005, Newport News presented by GlueX.

We observe two classes of anomalous signals in HCAL 2) Cherenkov light produced by interactions in the window of the Forward Calorimeter PMTs ¼ photoelectrons.

1 HF Laser/LED Calibration Studies L. Almeida, M. Baarmand, L. Caraway, M. Hohlmann, T. Qureshi, I. Vodopianov FLORIDA TECH 1->9 light splitter w/ pulsed.

Radiation therapy is based on the exposure of malign tumor cells to significant but well localized doses of radiation to destroy the tumor cells. The.

Hamamatsu R7525 HA: outer conductive coating with insulating sleeve CC: convex-concave window mm thick (standard plano-concave: 1mm center, 6.1.

TTU Group MeetingMarch 20, HF Radiation Damage Evaluation (What, how, what to do about it, and what is next?) *Phil Dudero (TTU)‏ Nural Akchurin.

LCG Meeting, May 14th 2003 V. Daniel Elvira1 G4 (OSCAR_1_4_0) Validation of CMS HCal V. Daniel Elvira Fermilab.

Status of Atlas Tile Calorimeter and Study of Muon Interactions L. Price for TileCal community Short Overview of the TileCal Project mechanics instrumentation.

Lecture 1.3: Interaction of Radiation with Matter

SHMS Optics and Background Studies Tanja Horn Hall C Summer Meeting 5 August 2008.

CMS Hadronic Endcap Calorimeter Upgrade Studies

N 2 Laser 300  QQ 150m HF  HF + 9 PMT Boxes  QP Calib Box 1  4 Counting Room HF Calibration Optical Fiber Path 9 PMT Boxes / Quad 24 PMT Tubes.

The Tungsten-Scintillating Fiber Accordion Electromagnetic Calorimeter for the sPHENIX Detector Craig Woody, for the PHENIX Collaboration Physics Department,

1 Prototype Calibration System for Forward Hadron Calorimeter L. Almeida, M. Baarmand, L. Caraway, M. Hohlmann, T. Qureshi, I. Vodopianov FLORIDA TECH.

CMS Calorimeter HB- HB+ HE- HE+ HF- HF+ HO-2 HO-1 HO0 HO+1 HO+2

NESTOR SIMULATION TOOLS AND METHODS Antonis Leisos Hellenic Open University Vlvnt Workhop.

Development of TOP counter for Super B factory K. Inami (Nagoya university) 2007/10/ th International Workshop on Ring Imaging Cherenkov Counters.

Lead Fluoride Calorimeter for Deeply Virtual Compton Scattering in Hall A Alexandre Camsonne Hall A Jefferson Laboratory October 31 st 2008.

EMCal in ALICE Norbert Novitzky 1. Outline How Electro-Magnetic Calorimeters works ? Physics motivation – What can we measure with Emcal ? – Advantages.

STUDY OF ULTRAREAR DECAYS K 0 → π 0 νν(bar) (Search of K 0 → π 0 νν(bar) decay at IHEP, project KLOD ) V.N. Bolotov on behalf of the collaboration JINR,

08-June-2006 / Mayda M. VelascoCALOR Chicago1 Initial Calibration for the CMS Hadronic Calorimeter Barrel Mayda M. Velasco Northwestern University.

The Electromagnetic Calorimeter – 2005 Operation J. Sowinski for the Collaboration and the Builders Indiana Univ. Michigan State Univ. ANL MIT BNL Penn.

Latifa Elouadrhiri Jefferson Lab Hall B 12 GeV Upgrade Drift Chamber Review Jefferson Lab March 6- 8, 2007 CLAS12 Drift Chambers Simulation and Event Reconstruction.

HF PRR – 16 February Core: 600 ± 10 micron dia Clad: micron dia Buffer: 800 ± 30 micron dia Core material: High OH- sythetic Silica.

HE CALORIMETER DETECTOR UPGRADE R&D Y. Onel for University of Iowa Fairfield University University of Mississippi.

Nov Beam Catcher in KOPIO (H. Mikata Kaon mini worksyop1 Beam Catcher in the KOPIO experiment Hideki Morii (Kyoto Univ.) for the KOPIO.

Mechanics and granularity considerations of a Tile hadronic calorimeter for FCC hh barrel Nikolay Topilin/Dubna+ Sergey Kolesnikov/Dubna Ana Henriques/CERN.

E. A. Albayrak, HCAL Meeting, Fermilab, Nov HE CALORIMETER DETECTOR UPGRADE R&D STATUS E. A. Albayrak for The University Of Iowa Fairfield University.

LHC The Large Hadron Collider (LHC) is an accelerator with 27 km circumference. Being built on the France- Switzerland border west of Geneva. It will start.

ATLAS Tile Hadronic Calorimeter:

FSC Status and Plans Pavel Semenov IHEP, Protvino on behalf of the IHEP PANDA group PANDA Russia workshop, ITEP 27 April 2010.

Rare decay Opportunities at U-70 Accelerator (IHEP, Protvino) Experiment KLOD Joint Project : IHEP,Protvino JINR,Dubna INR, Moscow, RAS.

October,05 HCAL Meeting 10/15/05 Quartz Plate Simulation Studies Quartz Plate Simulation Status F. Duru, U. Akgun, A.S. Ayan, J. Olson, Y. Onel The University.

Test beam results on the Proton Zero Degree Calorimeter for the ALICE experiment R. Gemme for the ALICE Collaboration  Universita’ del Piemonte Orientale.

Geant4 Tutorial, Oct28 th 2003V. Daniel Elvira Geant4 Simulation of the CMS 2002 Hcal Test Beam V. Daniel Elvira Geant4 Tutorial.

Upgrade of the LHCb ECAL monitoring system Yu. Guz (IHEP Protvino / CERN), on behalf of the LHCb collaboration 07/04/2014.

Christopher Cowden Advisor: Mario Spezziga Project: CMS HF (Forward Calorimeter)

Calorimeters Design Issues and Simulation Needs C.Woody Physics Department Brookhaven National Lab EIC Simulation Workshop Oct 9, 2012.

1 ZDCs in CMS Michael Murray,U Kansas pp Lum EMHad PMTs Lead/ plastic Fiber 1.5cm tungsten plates 2mm plates Beam LED Spare space for flow upgrade Light.

Radiation Damage Studies for Si Diode Sensors Subject to MRaD Doses Bruce Schum UC Santa Cruz July

1 Plannar Active Absorber Calorimeter Adam Para, Niki Saoulidou, Hans Wenzel, Shin-Shan Yu Fermialb Tianchi Zhao University of Washington ACFA Meeting.

NEVOD-DECOR experiment: results and future A.A.Petrukhin for Russian-Italian Collaboration Contents MSU, May 16, New method of EAS investigations.

The ATLAS Tile hadron calorimeter The ATLAS Tile hadron calorimeter Ana Henriques/CERN on behalf of the ATLAS collaboration ANIMMA 2015, April Content:

Tested: 15 types of LEDs (blue, green); quartz fibers with core diameters of 300µm and 50µm. Proposal: Blue LEDs rather than green: + : larger signal,

PbWO 4 crystals Calorimeter Liping Gan University of North Carolina Wilmington.

Simulation studies of total absorption calorimeter Development of heavy crystals for scintillation and cherenkov readout Dual readout in the 4 th concept.

SPHENIX Mid-rapidity extensions: Additional Tracking system and pre-shower Y. Akiba (RIKEN/RBRC) sPHENIX workfest July 29,

1 Status of Zero Degree Calorimeter for CMS Experiment O.Grachov, M.Murray University of Kansas, Lawrence, KS A.S.Ayan, P.Debbins, E.Norbeck, Y.Onel University.

CALOR 2012 Vardan Tadevosyan XVth International Conference on Calorimetry in High Energy Physics Santa Fe, NM, June 4 – 8,

DE/dx in ATLAS TILECAL Els Koffeman Atlas/Nikhef Sources: PDG DRDC (1995) report RD34 collaboration CERN-PPE

Tracker Neutron Detector: INFN plans CLAS12 Central Detector Meeting - Saclay 2-3 December 2009 Patrizia Rossi for the INFN groups: Genova, Laboratori.

K2K and JHF-nu muon monitor Jun Kameda (KEK) 1. K2K muon monitor 2. JHF-ν muon monitor 3. Summary International workshop on Neutrino Beam Instrumentation,

Status of Zero Degree Calorimeter for CMS Experiment

“Performance test of a lead glass

HF QUARTZ FIBER Y.Onel , J.P.Merlo, K.Cankocak, I.Dumanoglu, I.Schmidt and A.Penzo.

K2K and JHF-nu muon monitor

Calorimeters in HEP Add hermiticity CC event - calibration

PARTICLE FLUX CALCULATION-III

Multianode Photo Multipliers for Ring Imaging Cherenkov Detectors

Fassò, N. Nakao, H. Vincke Aug. 2, 2005

Particles going through matter

Presentation transcript:

APS April2000 Meeting Ahmet Sedat Ayan Dept. of Physics & Astronomy University of Iowa

Why HF?  Covers the pseudorapidity range 3-5  HF psedorapidity range will get 100Mrad/year. Therefore the detector should be able to withstand this exceptionally high radiation field.  Two main objectives : 1. To improve the measurement of the missing transverse energy E miss T 2. To enable identification and reconstruction of very forward jets

CMS Longitudinal View

HF Calibration Readout Boxes Photo detectors Transporter FE, Trig/DAQ DCS, Voltage Shielding Absorber Optics Quartz Fibers

HF Transverse Segmentation QQ/QP Border 3 <  < 5 HF is segmented in  =  = EM(31/20-deg) HAD(25/20-deg) TC(13/20-deg) TOTAL(69/20-deg) The active region extends from r=12.5 cm to 130 cm.The depth is 165 cm (Fe).

Experimental Technique Light is generated by Cherenkov effect in quartz fibers Sensitive to relativistic charged particles (Compton electrons...) d 2 N/dxdl=2paz 2 (sin 2 q/l 2 ) =(2paz 2 / l 2 )[1-1/b 2 n 2 ] b min = 1/n E min ~ 200 keV Amount of collected light depends on the angle between the particle path and the fiber axis

HF PPP1 Side View Fiber Bundles (EM, HAD and TC) 300-micron core QP Ferrules ROBox ( Light Guides) R6425 PMTs Iron Absorber (9.5 l I ) Radioactive Source Tubes 3 x 3 Tower structure (6 cm x 6 cm) LED, Laser and PIN PDs

2.5 mm TC (30 cm) HAD (143 cm) EM (165 cm) HF Longitudinal Segmentation EMHAD TC

Uniformity Scan with Electrons There is a +/- 6 % response nonuniformity to electrons due to fiber periodicity at every 2.5 mm (5 mm for EM).

Response to Electrons and Pions HF PPP1 responds linearly within 1% to electrons in the energy range tested (6 – 200 GeV). The pion (neg) response is highly nonlinear.

Electromagnetic Energy Resolution Electromagnetic energy resolution is completely dominated by photostatistics (N p.e. ). The usual parametrization, a/sqrt(E) + b, results in a~192% and b~9% for the PPP % fiber fraction degrades the EM energy resolution by a ~sqrt(2) compared to HAD95 (1.6%). 137%/sqrt(E) with 1.6% fiber packing Fraction (HAD95)

Hadronic Energy Resolution Hadronic energy resolution is dominated by non-stochastic processes at higher energies. Photo statistics becomes important only at lower energies. The intrinsic energy resolution can be expressed as c-d*ln(E). The expected energy resolution at 1 TeV is 18%.

FLUKACalculations FLUKA Calculations  Recent radiation background simulations show improvement in the design of the shielding around the PMT region by a factor of ~two. There is no issue with the radiation dose or neutron flux where the PMTs are located.  All neutrons2.54x10 12  Neutrons (E>100KeV) 1.63x10 12  Neutrons (E>20 MeV) 5.12x10 11  Ch. Hadrons2.26x10 10  Muons4.65x10 9  Photons1.53x10 12  Dose7 krad

OpticsFiberRadiation Damage Optics: Fiber Radiation Damage Several quartz fiber irradiation studies have been carried out in the last several years. The induced attenuation profile shows that there is less absorbtion in nm (PMT) region compared to either shorter or longer wavelengths. ~200 MRad 63% loss

PPP-I Summary  1% linearity in response to electrons. Highly non-linear to negative pions  Electromagnetic Energy Resolution: 192%  9%  Expected Hadronic Energy Resolution at 1TeV is 18%  +/- 6% non-uniformity in response to electrons due to fiber periodicity  Suppressed induced radiation damage on fibers  in PMT region ( nm)