2002 IEEE NSS Dmitri Denisov, Fermilab Forward Muon System for the D0 Experiment Presented by Dmitri Denisov Fermilab For the D0 Collaboration 644 members.

Slides:



Advertisements
Similar presentations
Beam-plug and shielding studies related to HCAL and M2 Robert Paluch, Burkhard Schmidt November 25,
Advertisements

LHCf: a LHC Detector for Astroparticle Physics LHCf: a LHC Detector for Astroparticle Physics Lorenzo Bonechi on behalf of the LHCf Collaboration * University.
M. Palm, CERN1 Performance test of ACEM-detector (Aluminum Cathode Electron Multiplier) Marcus Palm AB-ATB-EA.
Introduction to Hadronic Final State Reconstruction in Collider Experiments Introduction to Hadronic Final State Reconstruction in Collider Experiments.
Recent Electroweak Results from the Tevatron Weak Interactions and Neutrinos Workshop Delphi, Greece, 6-11 June, 2005 Dhiman Chakraborty Northern Illinois.
The new Silicon detector at RunIIb Tevatron II: the world’s highest energy collider What’s new?  Data will be collected from 5 to 15 fb -1 at  s=1.96.
The performance of LHCf calorimeter was tested at CERN SPS in For electron of GeV, the energy resolution is < 5% and the position resolution.
Electroweak Physics at the Tevatron Adam Lyon / Fermilab for the DØ and CDF collaborations 15 th Topical Conference on Hadron Collider Physics June 2004.
Description of BTeV detector Jianchun Wang Syracuse University Representing The BTeV Collaboration DPF 2000 Aug , 2000 Columbus, Ohio.
Forward Detectors and Measurement of Proton-Antiproton Collision Rates by Zachary Einzig, Mentor Michele Gallinaro INTRODUCTION THE DETECTORS EXPERIMENTAL.
The CMS Muon Detector Thomas Hebbeker Aachen July 2001 Searching for New Physics with High Energy Muons.
APS Meeting April 5-8, 2003 at Philadelphia Chunhui Luo 1 Chunhui Luo Inclusive J/ψ Production at DØ.
Workshop on Quarkonium, November 8-10, 2002 at CERN Heriberto Castilla DØ at Run IIa as the new B-Physics/charmonium player Heriberto Castilla Cinvestav-IPN.
Hamamatsu R7525 HA: outer conductive coating with insulating sleeve CC: convex-concave window mm thick (standard plano-concave: 1mm center, 6.1.
EPS 2003, July 19, 2003David Buchholz, Northwestern University Performance of the D0 Experiment in Run II Detector Commissioning and Performance Accelerator,
BEACH Conference 2006 Leah Welty Indiana University BEACH /7/06.
The Transverse detector is made of an array of 256 scintillating fibers coupled to Avalanche PhotoDiodes (APD). The small size of the fibers (5X5mm) results.
Scientific Highlights : CDF Experiment 1.Introduction 2.CDF Run-II detector 3.Phyiscs highlights B Physics, Top, Higgs, … to be continued by Rob October.
PERFORMANCE OF THE MACRO LIMITED STREAMER TUBES IN DRIFT MODE FOR MEASUREMENTS OF MUON ENERGY - Use of the MACRO limited streamer tubes in drift mode -Use.
W properties AT CDF J. E. Garcia INFN Pisa. Outline Corfu Summer Institute Corfu Summer Institute September 10 th 2 1.CDF detector 2.W cross section measurements.
Jornadas LIP 2008 – Pedro Ramalhete. 17 m hadron absorber vertex region 8 MWPCs 4 trigger hodoscopes toroidal magnet dipole magnet hadron absorber targets.
Precision Drift Chambers for the ATLAS Muon Spectrometer Susanne Mohrdieck Max-Planck-Institut f. Physik, Munich for the ATLAS Muon Collaboration Abstracts:
Status of the NO ν A Near Detector Prototype Timothy Kutnink Iowa State University For the NOvA Collaboration.
Scintillation hodoscope with SiPM readout for the CLAS detector S. Stepanyan (JLAB) IEEE conference, Dresden, October 21, 2008.
Muon Detector Jiawen ZHANG Introduction The Detector Choices Simulation The structure and detector design The Expected performance Schedule.
NanoPHYS’12 – December 17-19, 2012 K. Nakano, S. Miyasaka, K. Nagai and S. Obata (Department of Physics, Tokyo Institute of Technology) Drift Chambers.
Design and development of micro-strip stacked module prototypes for tracking at S-LHC Motivations Tracking detectors at future hadron colliders will operate.
Multiple Parton Interaction Studies at DØ Multiple Parton Interaction Studies at DØ Don Lincoln Fermilab on behalf of the DØ Collaboration Don Lincoln.
Forward Muon Installation and Commissioning Dmitri Denisov Fermilab Director’s review 7/12/1999 Plan Forward muon detectors Mini-drift tubes installation.
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.
BES-III Workshop Oct.2001,Beijing The BESIII Luminosity Monitor High Energy Physics Group Dept. of Modern Physics,USTC P.O.Box 4 Hefei,
Apollo Go, NCU Taiwan BES III Luminosity Monitor Apollo Go National Central University, Taiwan September 16, 2002.
Tevatron II: the world’s highest energy collider What’s new?  Data will be collected from 5 to 15 fb -1 at  s=1.96 TeV  Instantaneous luminosity will.
Luca Spogli Università Roma Tre & INFN Roma Tre
All Experimenters MeetingDmitri Denisov Week of July 7 to July 15 Summary  Delivered luminosity and operating efficiency u Delivered: 1.4pb -1 u Recorded:
The RICH Detectors of the LHCb Experiment Carmelo D’Ambrosio (CERN) on behalf of the LHCb RICH Collaboration LHCb RICH1 and RICH2 The photon detector:
Aurelio Juste (Fermilab) Rencontres de Moriond, March OUTLINE Tevatron Run 2 The upgraded DØ Detector Status Performance First Physics Results Outlook.
Precision Drift Chambers for the ATLAS Muon Spectrometer
FSC Status and Plans Pavel Semenov IHEP, Protvino on behalf of the IHEP PANDA group PANDA Russia workshop, ITEP 27 April 2010.
Magnetized hadronic calorimeter and muon veto for the K +   +  experiment L. DiLella, May 25, 2004 Purpose:  Provide pion – muon separation (muon veto)
PERFORMANCE OF THE PHENIX SOUTH MUON ARM Kenneth F. Read Oak Ridge National Lab & University of Tennessee for the PHENIX Collaboration Quark Matter 2002.
2002 LHC days in Split Sandra Horvat 08 – 12 October, Ruđer Bošković Institute, Zagreb Max-Planck-Institute for Physics, Munich Potential is here...
Susan Burke DØ/University of Arizona DPF 2006 Measurement of the top pair production cross section at DØ using dilepton and lepton + track events Susan.
Detectors for VEPP-2000 B.Khazin Budker Institute of Nuclear Physics 2 March 2006.
Penny Kasper Fermilab Heavy Quarkonium Workshop 21 June Upsilon production DØ Penny Kasper Fermilab (DØ collaboration) 29 June 2006 Heavy Quarkonium.
January 13, 2004A. Cherlin1 Preliminary results from the 2000 run of CERES on low-mass e + e - pair production in Pb-Au collisions at 158 A GeV A. Cherlin.
DØ Beauty Physics in Run II Rick Jesik Imperial College BEACH 2002 V International Conference on Hyperons, Charm and Beauty Hadrons Vancouver, BC, June.
1 Experimental Particle Physics PHYS6011 Fergus Wilson, RAL 1.Introduction & Accelerators 2.Particle Interactions and Detectors (2) 3.Collider Experiments.
Station-4 MuID System: Status Ming X. Liu Los Alamos National Lab 1/7/091E906 Collaboration Meeting.
P.F.Ermolov SVD-2 status and experimental program VHMP 16 April 2005 SVD-2 status and experimental program 1.SVD history 2.SVD-2 setup 3.Experiment characteristics.
Siena, May A.Tonazzo –Performance of ATLAS MDT chambers /1 Performance of BIL tracking chambers for the ATLAS muon spectrometer A.Baroncelli,
Introduction to Hadronic Final State Reconstruction in Collider Experiments Introduction to Hadronic Final State Reconstruction in Collider Experiments.
Nikhef Scientific Meeting 2000Onne Peters D0 Muon Spectrometer December 14-15, Amsterdam Onne Peters Nikhef Jamboree 2000.
Precision Drift Tube Detectors for High Counting Rates O. Kortner, H. Kroha, F. Legger, R. Richter Max-Planck-Institut für Physik, Munich, Germany A. Engl,
The New CHOD detector for the NA62 experiment at CERN S
The Transition Radiation Detector for the PAMELA Experiment
Entrance Muon Counter (EMC)
CMS muon detectors and muon system performance
Panagiotis Kokkas Univ. of Ioannina
The Compact Muon Solenoid Detector
Kevin Burkett Harvard University June 12, 2001
VEPP-2000 plans for the study of the nucleon form factors
Experimental Particle Physics PHYS6011 Putting it all together Lecture 4 6th May 2009 Fergus Wilson, RAL.
Higgs Factory Backgrounds
GEANT Simulations and Track Reconstruction
Performance test of ACEM-detector (Aluminum Cathode Electron Multiplier) Marcus Palm AB-ATB-EA M. Palm, CERN.
Experimental Particle Physics PHYS6011 Putting it all together Lecture 4 28th April 2008 Fergus Wilson. RAL.
Experimental Particle Physics PHYS6011 Joel Goldstein, RAL
Background Simulations at Fermilab
Susan Burke, University of Arizona
Presentation transcript:

2002 IEEE NSS Dmitri Denisov, Fermilab Forward Muon System for the D0 Experiment Presented by Dmitri Denisov Fermilab For the D0 Collaboration 644 members 73 institutions 18 countries D0 Note 4061 November 2002

2002 IEEE NSS Dmitri Denisov, Fermilab Fermilab Tevatron Upgrade Tevatron Run 1 ( ) produced reach harvest of interesting physics results, including top quark discovery In order to continue studies at the energy frontier Tevatron underwent serious upgrade in factor of ~10 higher luminosity factor of ~10 smaller bunch spacing Physics goals for Tevatron Run 2: precision studies of weak bosons, top, QCD, B-physics searches for Higgs, supersymmetry, extra dimensions, other new phenomena Interactions / xing Bunch xing (ns)  Ldt (pb -1 /week) 5.2    Typical L (cm -2 s -1 )  s (TeV) 140   366  6 Bunches in Turn Run 2bRun 2aRun 1b Run 1  Run 2a  Run 2b 0.1 fb -1  2  4 fb -1  15 fb -1

2002 IEEE NSS Dmitri Denisov, Fermilab Challenges for the Tevatron Run 2 Detectors  In order to fully exploit Tevatron capabilities in Run 2 D0 detector has been substantially upgraded  smaller bunch crossing of 132ns (vs 3.1  s) required replacement of electronics as well as some of the slow detectors u higher luminosity provides higher radiation fluxes and requires more radiation hard detectors u higher event rate requires better trigger systems in order to select only ~10 -5 of the interactions which can be written to tapes u new detectors have been added in order to improve detection of displaced vertices and provide momentum measurement in the central region  Forward muon system of the D0 detector covers rapidity region between 1.0 and 2.0 and has been fully redesigned for Run 2 u separated functions of muon tracking and trigger detectors u fast detectors with internal resolution time below 60ns u radiation hard detectors u detectors capable of operating in the magnetic field of the muon toroid and central solenoid u time and coordinate resolution provide efficient muon detection and backgrounds suppression

2002 IEEE NSS Dmitri Denisov, Fermilab D0 Detector for Run II Forward MDT Layers C B A A-  Counters Pixel Counter Layers A B C New 2T Solenoid PDT Chambers C B A Outer Counters Shielding Preshower Fiber Tracker Silicon Tracker Electronics

2002 IEEE NSS Dmitri Denisov, Fermilab Forward Muon System  Forward muon system consists of the following major elements u shielding around Tevatron beam pipe s provides factor of ~100 reduction in backgrounds u trigger system based on 3 layers of scintillation trigger counters s 4608 scintillation counters with ~1ns time resolution u tracking system based on 3 layers of mini-drift tubes s 50,000 wires assembled in 8 wires extrusion assemblies s maximum drift time is 60ns s coordinate resolution is 0.7mm Forward scintillation counters Shielding Mini- drift tubes

2002 IEEE NSS Dmitri Denisov, Fermilab Shielding  There are two major sources of backgrounds(non-muon) hits in muon detectors at hadron colliders u background particles coming from the accelerator tunnel u background particles originated in interactions of p-pbar collision products propagating at small angles with accelerator and detector equipment  Both of these backgrounds can be substantially reduced by placing shielding around beam pipe u consists of 3 layers s 50 cm of steel - absorb hadrons and e/gamma s 12 cm of polyethylene - absorb neutrons s 5 cm of lead - absorb gamma rays u calculations based on GEANT/MARS codes demonstrate reduction in particle fluxes for shielded/unshielded detectors by a factor of s Run 1 muon detector occupancies have been in the 5- 10% level s Run 2 muon detector occupancies are in the % level in good agreement with calculations u use of detectors less sensitive to backgrounds (high time resolution, small sensitive volume, etc.) provides advantages as well

2002 IEEE NSS Dmitri Denisov, Fermilab Shielding Effect of the shielding on background fluxes: factor of reduction Without ShieldingWith Shielding Hadron e/gamma

2002 IEEE NSS Dmitri Denisov, Fermilab Trigger Scintillation Counters  3 planes of ~10x10m 2 on both sides of the interaction region  Counters arranged in R-  geometry matching central fiber tracker trigger  Total number of counters 4608  Major specifications u fine segmentation u time resolution of ~1ns to separate tracks coming from interaction region from cosmic and accelerator tunnel u low radiation aging u operation in magnetic field up to ~350Gs  Simple and reliable design has been developed u based on 12mm thick Bicron 404A scintillator u light collection is performed using WLS bars u fast 25mm diameter phototubes are used for light collection 10x10m 2 plane of counters assembled in “fish scale” design in the collision hall

2002 IEEE NSS Dmitri Denisov, Fermilab Trigger Scintillation Counters Cut to shape 404A scintillator with two Kumarin WLS bars attached collect light on the 25mm photocathode of 115M (MELZ) phototube Tyvek wrapping is used for better light collection Counters sizes are from 10x10cm 2 to 1x1m 2 Average number of phe for large counters is 60 Time resolution is 0.5-1ns depending on counter size limited by photoelectron statistics and amplitude fluctuations (single threshold discriminator) Amplitude response uniformity is ~10% Radiation aging for 15fb -1 integrated luminosity (Run II Tevatron goal) Pair Kumarin(WLS)+404A(Scintillator) demonstrates 10% light loss for 20krad irradiation. We expect doses for the hottest regions to be well below 1krad (15fb -1 ) Phototube 115M losses 10% of gain for anode accumulated charge of 100C (15fb -1 ). This could be easily compensated by HV adjustment Counter Design

2002 IEEE NSS Dmitri Denisov, Fermilab Magnetic Shielding  Magnetic shielding is provided with u 1.2mm thick mu-metal u 3mm or 6mm tick soft iron shield u transverse to tube axis field has no effect up to ~700Gs u field parallel to the tube affects phototubes s 3mm iron shield (closed circles): 10% gain loss at 250Gs –used in layers outside muon toroid s 6mm iron shield (open circles): 10% gain loss at 350Gs –used in layer inside muon toroid u LED tests with/without field s less then 1-2% effect for all 4608 tubes

2002 IEEE NSS Dmitri Denisov, Fermilab Counters Performance During Data Taking  During collider data collection performance of all counters is monitored u efficiency of individual planes and counters based on reconstructed muon tracks s stable above 99% u gain of all phototubes with respect to reference calibration set using LED system s peak position stable within ~2% over one year of operation s typical variations in the gain do not exceed ~5% u timing characteristics s peak of LED pulse is stable within 0.5ns over a year of operation s peak and width of the timing spectra for muon tracks  Total number of “dead” counters after 1 year of operation is 5 (0.1%) 1 year LED timing stability Timing peak for muon tracks  =1.8ns  =0.5ns

2002 IEEE NSS Dmitri Denisov, Fermilab Forward Muon Tracking Detector  Forward muon tracking detector is based on mini- drift tubes u 1x1cm 2 drift cell u 8 cell aluminum extrusion comb with 0.7mm thick walls (to reduce dead zones) u stainless steel cover and PVC sleeve provides electrical field configuration and gas tight volume Tubes length vary between 1m and 6m 50mm gold plated tungsten wire is supported every meter Total number of wires in the system is 50,000 Tubes are assembled into 8 octants per layer with wires parallel to magnetic field lines There are 4 planes of wires in layer before toroid and 3 planes of wires in each of two layers after toroid muon has 10 hits on track average

2002 IEEE NSS Dmitri Denisov, Fermilab Working Gas for Mini-drift Tubes  We are using CF 4 (90%)+CH 4 (10%) gas mixture u non-flammable u very fast u re-circulation with small losses (~5%) reduces gas cost u no radiation aging u wide 100% efficiency mip platou s 2.9kV-3.4kV  Time-to-distance dependence has been measured and simulated u maximum drift time for tracks perpendicular to the plane is ~40ns u maximum dirft time for 45 degree tracks is ~60ns  Coordinate resolution of the mini-drift tube system is defined by electronics u TDC bin is 19ns (cost driven)   =0.7mm u starts affect “muon system only” coordinate resolution for muon momentum above 50GeV/c Accumulated charge for 15fb -1 is estimated at 30mC/cm Aging test with Sr 90 r/a source demonstrates no aging effects up to 2C/cm With large safety factor mini-drift tubes radiation aging is not an issue

2002 IEEE NSS Dmitri Denisov, Fermilab Mini-drift Tubes Performance  During data collection many parameters of the mini-drift tubes are monitored u gas flow s ~32 tubes are connected in serial with input/output flow monitoring u high voltage values and currents s all 50,000 wires operates at the same high voltage of 3.25kV u individual planes efficiency using reconstructed muon segments s typical efficiency is in the range above 99% u plane coordinate accuracy using reconstructed segments  Reliability u total number of disabled wires s 0.3% after commissioning –dead or noisy s increase in number of disabled wires is less then 0.1% per year of operation Coordinate resolution of mini-drift tube plane based on local segment reconstruction RMS=0.7mm

2002 IEEE NSS Dmitri Denisov, Fermilab Forward Muon System Performance  Low occupancy of the forward muon detectors due to well designed shielding and use of fast detectors proved to be very low u at the 0.05%-0.1% level u simple and reliable muon triggering s after Level 1 trigger (scintillation counters only) 50% of events have good muon reconstructed off-line s after Level 2 trigger (mini-drift tubes and scintillation counters) 80% of events have good track reconstructed off-line –writing to tapes background free samples u simple and background free muon off-line reconstruction  High reliability of forward muon detectors provided above 99% “up-time” during physics data collection  Based on efficient muon hits detection, triggering, and reconstruction D0 forward muon system is providing data for wide spectrum of physics studies at the energy frontier at the Tevatron  Some important issues like alignment, electronics, triggering, reconstruction are not addressed due to limited talk time M = 3.08  0.04 GeV  = 0.78  0.08 GeV Single Muon Event

2002 IEEE NSS Dmitri Denisov, Fermilab Summary: D0 Forward Muon System  D0 experiment developed and constructed multi-layer steel+poly+lead shielding which reduced background fluxes on the muon detectors by a factor of u reduction in detectors aging, trigger rates, fake tracks  Separation of triggering and tracking capabilities in the D0 forward muon system provides background free muon samples to be written to tapes  Forward muon trigger system based on 4608 scintillation counters u simple and reliable counter design for counters from 10x10cm 2 to 1x1m 2 u time resolution of ~1ns u provides above 60 phe per mip u radiation hard to well above 100kRad u phototube magnetic shield provides reliable operation up to 350Gs  Forward muon tracking system u 50,000 wires of mini-drift tubes with 1x1cm 2 drift cells and length up to 6m s modular extrusion based tube design u CF 4 (90%)+CH 4 (10%) gas mixture s fast, 60ns max drift time s non-flammable s radiation hard above 2C/cm s wide HV operating plateau of 0.5kV  All system elements reached or exceeded Run II specifications and operate smoothly during over a year of data taking