Performance of the PHENIX NCC Prototype Michael Merkin Skobeltyn Institute of Nuclear Physics Moscow State University.

Slides:

Advertisements

Similar presentations

LC Calorimeter Testbeam Requirements Sufficient data for Energy Flow algorithm development Provide data for calorimeter tracking algorithms  Help setting.

Advertisements

An SiPM Based Readout for the sPHENIX Calorimeters Eric J. Mannel IEEE NSS/MIC October 30, 2013.

J-C. BRIENT (LLR) 1  Introduction with pictures  Prototype design and construction  R&D on the design of the full scale calorimeter CALICE - ECAL silicon-tungsten.

Bulk Micromegas Our Micromegas detectors are fabricated using the Bulk technology The fabrication consists in the lamination of a steel woven mesh and.

W. Clarida, HCAL Meeting, Fermilab Oct. 06 Quartz Plate Calorimeter Prototype Geant4 Simulation Progress W. Clarida The University of Iowa.

Adding electronic noise and pedestals to the CALICE simulation LCWS 19 – 23 rd April Catherine Fry (working with D Bowerman) Imperial College London.

Front-end electronics for Time Projection Chamber I.Konorov Outlook:  TPC requirements  TPC readout options  Options for TPC FE chips  Prototype TPC.

TileCal Electronics A Status Report J. Pilcher 17-Sept-1998.

Ionization. Measuring Ions A beam of charged particles will ionize gas. –Particle energy E –Chamber area A An applied field will cause ions and electrons.

SiLC Front-End Electronics LPNHE Paris March 15 th 2004.

28 June 2002Santa Cruz LC Retreat M. Breidenbach1 SD – Silicon Detector EM Calorimetry.

27 th May 2004Daniel Bowerman1 Dan Bowerman Imperial College 27 th May 2004 Status of the Calice Electromagnetic Calorimeter.

E.Kistenev, Forward Upgrade Meeting 08/18/04 Forward (Nose Cone) Calorimeter: Update 2.5 mm.

Preliminary Design of Calorimeter Electronics Shudi Gu June 2002.

Shashlik type calorimeter for SHIP experiment

A. Sukhanov, BNL1 NCC Electronics Readout of pad structured sensors ● High dynamic range ● Summing signals from 6 detectors on one preamp ● NCC should.

Roger Rusack – The University of Minnesota 1.

A. Sukhanov, BNL1 NCC Electronics Readout of pad structured sensors ● High dynamic range: 14 bit range, 10 bit accuracy ● Summing signals from 6 detectors.

Prospect for Si sensors in Korea Y. Kwon (Yonsei Univ.)

Ingrid-Maria Gregor Der Silizium Recoil Detektor für HERMES Technisches Seminar DESY Zeuthen 8. April 2003 m Introduction m HERMES at DESY Hamburg m What.

Montpellier, November 12, 2003Vaclav Vrba, Institute of Physics, AS CR 1 Vaclav Vrba Institute of Physics, AS CR, Prague CALICE ECal Status Report.

Radiation Detectors Khayrudinov Vladislav Ismail Belmostefa XX00AA Sensor Technology Helsinki Metropolia University of Applied Sciences 2014.

Peter, Wieczorek - EE Low Noise Charge Sensitive Preamplifier Development for the PANDA Calorimeter Design and Measurements of the APFEL - Chip.

The ALICE Forward Multiplicity Detector Kristján Gulbrandsen Niels Bohr Institute for the ALICE Collaboration.

The ZEUS Hadron-Electron-Separator Performance and Experience Peter Göttlicher (DESY) for the ZEUS-HES-group Contributions to HES Germany, Israel, Japan,

Pion Showers in Highly Granular Calorimeters Jaroslav Cvach on behalf of the CALICE Collaboration Institute of Physics of the ASCR, Na Slovance 2, CZ -

March 2004 CALOR 2004, Perugia, Italy Super-dense W-Si Calorimeter for the Forward Spectrometer Upgrade of PHENIX at RHIC (*) on behalf of the PHENIX Forward.

M. Chefdeville LAPP, Annecy, France. Introduction  Motivations for a Digital hadronic calorimeter Count hits instead of measuring energy deposits Reduce.

8 July 1999A. Peisert, N. Zamiatin1 Silicon Detectors Status Anna Peisert, Cern Nikolai Zamiatin, JINR Plan Design R&D results Specifications Status of.

V.Dzhordzhadze1 Nosecone Calorimeter Simulation Vasily Dzhordzhadze University of Tennessee Muon Physics and Forward Upgrades Workshop Santa Fe, June 22,

At the HERA collider in Hamburg an experiment (ZEUS) has been built to study electron-proton collisions. For the near future an upgrade of this experiment.

Update on final LAV front-end M. Raggi, T. Spadaro, P. Valente & G. Corradi, C. Paglia, D. Tagnani.

Apollo Go, NCU Taiwan BES III Luminosity Monitor Apollo Go National Central University, Taiwan September 16, 2002.

ECAL PID1 Particle identification in ECAL Yuri Kharlov, Alexander Artamonov IHEP, Protvino CBM collaboration meeting

ICPPA-2015 Moscow Oct ASIC for calorimetric measurements in astrophysical experiment NUCLEON (overview) E. Atkin1, A. Voronin1,2, D. Karmanov2,

Solid State Detectors for Upgraded PHENIX Detector at RHIC.

Silicon sensors for LumiCal Two possible options Wojciech Wierba Institute of Nuclear Physics PAN Cracow.

- Performance Studies & Production of the LHCb Silicon Tracker Stefan Koestner (University Zurich) on behalf of the Silicon Tracker Collaboration IT -

AIDA design review Davide Braga Steve Thomas ASIC Design Group 9 December 2008.

ASIC Activities for the PANDA GSI Peter Wieczorek.

11/18/2016 Test beam studies of the W-Si tracking calorimeter for the PHENIX forward upgrade Y. Kwon, Yonsei Univ., PHENIX.

Pixel detector development: sensor

August DESY-HH VFCAL Report W. Lohmann, DESY Infrastructure for sensor diagnostics FE Electronics Development Sensor test facilities Laser Alignment.

11 October 2002Paul Dauncey - CDR Introduction1 CDR Introduction and Overview Paul Dauncey Imperial College London.

A Silicon Photomultiplier (SiPM) Based Readout for the sPHENIX Upgrade S. Boose, J. Haggerty, E. Mannel, A. Sukhanov For the PHENIX Collaboration Introduction:

Lucia Bortko | Optimisation Studies for the BeamCal Design | | IFJ PAN Krakow | Page 1/16 Optimisation Studies for the BeamCal Design Lucia.

Analog readout for the forward NC Calorimeter (W-Si) BNL, Physics, 06/06/30 E.Kistenev.

Proposal of a digital-analog RPC front-end for synchronous density particle measure for DHCAL application R.Cardarelli and R.Santonico INFN and University.

DHCAL Jan Blaha R&D is in framework of the CALICE collaboration CLIC08 Workshop CERN, 14 – 17 October 2008.

Extending Physics Capabilities of the PHENIX Detector with Calorimetry at Forward Rapidities Vasily Dzhordzhadze University of California, Riverside for.

Front-end Electronic for the CALICE ECAL Physic Prototype Christophe de La Taille Julien Fleury Gisèle Martin-Chassard Front-end Electronic for the CALICE.

Flex Cable Readout unit Si Sensor 256 analog lines Interconnect board NCC signal packaging concept PA board -This is the calorimeter – all pads in the.

MICRO-STRIP METAL DETECTOR FOR BEAM DIAGNOSTICS PRINCIPLE OF OPERATION Passing through metal strips a beam of charged particles or synchrotron radiation.

A Forward Calorimeter (FoCal) as upgrade for the ALICE experiment at CERN S. Muhuri a, M. Reicher b and T. Tsuji c a Variable Energy Cyclotron Centre,

Study of the MPPC for the GLD Calorimeter Readout Satoru Uozumi (Shinshu University) for the GLD Calorimeter Group Kobe Introduction Performance.

Status of hardware activity in CNS Taku Gunji Center for Nuclear Study University of Tokyo 1.

M. Manghisoni, L. Ratti Università degli Studi di Pavia INFN Pavia

A General Purpose Charge Readout Chip for TPC Applications

FCAL R&D towards a prototype of very compact calorimeter

CEPC 数字强子量能器读出电子学预研进展

A Forward Calorimeter (FoCal) as upgrade for the ALICE experiment at CERN S. Muhuria , M. Reicherb and T. Tsujic a Variable Energy Cyclotron Centre,

Application of VATAGP7 ASICs in the Silicon detectors for the central tracker (forward part) S. Khabarov, A. Makankin, N. Zamiatin, ,

Silicon Pixel Detector for the PHENIX experiment at the BNL RHIC

detector development readout electronics interconnects bump bonding

Panagiotis Kokkas Univ. of Ioannina

Detection of muons at 150 GeV/c with a CMS Preshower Prototype

A Low Power Readout ASIC for Time Projection Chambers in 65nm CMOS

BESIII EMC electronics

Simulation study for Forward Calorimeter in LHC-ALICE experiment

LC Calorimeter Testbeam Requirements

Presentation transcript:

Performance of the PHENIX NCC Prototype Michael Merkin Skobeltyn Institute of Nuclear Physics Moscow State University

6/5/06 2 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin NCC Structure NCC Structure Electromagnetic part – layers with 0.7 – 1.2 L rad Hadron part – 6 layers with 17 mm W Two stripixel layers preshower and shower MAX detectors

6/5/06 3 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin NCC Prototype. Overview

6/5/06 4 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin NCC Prototype Parts

6/5/06 5 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin NCC Prototype: Sensor NCC Prototype: Sensor

6/5/06 6 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Thickness um (525 – plans for real device) Thickness um (525 – plans for real device) Silicon Resistivity >5 кОмсм Silicon Resistivity >5 кОмсм Pads -16, 15 * 15 mm 2 each Pads -16, 15 * 15 mm 2 each Sensor size 62 * 62 mm 2 Sensor size 62 * 62 mm 2 Active area 60 * 60 mm 2 Active area 60 * 60 mm 2 One pad capacitance – 70 pF One pad capacitance – 70 pF Full Depletion Voltage (FDV) – 25 – 45 V Full Depletion Voltage (FDV) – 25 – 45 V Sensor Parameters

6/5/06 7 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Sensor Parameters

6/5/06 8 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Sensor Board

6/5/06 9 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Front-End Electronics - CR-1.4 High dynamic range ~2500 MIPs High dynamic range ~2500 MIPs Noise e e - /pF Noise e e - /pF Number of channels per chip/board - 16 Number of channels per chip/board - 16

6/5/06 10 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Charge Sensitive preamplifier Charge Sensitive preamplifier Shaper Shaper Analog pipeline Analog pipeline Multiplexer Multiplexer Front-End Electronics - CR-1.4

6/5/06 11 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Readout electronics, charge sensitive amplifier CR-1 Readout electronics, charge sensitive amplifier CR-1

6/5/06 12 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin NCC requirements* Energy resolution for one shower at least: σ/E=0.25/E 1/2 Energy resolution for one shower at least: σ/E=0.25/E 1/2 Two showers resolution in case: π 0 → γγ Two showers resolution in case: π 0 → γγ Electronics dynamic range >1000 MIP at 1 MIP resolution. Electronics dynamic range >1000 MIP at 1 MIP resolution. *See E.Kistenev presentation

6/5/06 13 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Direct connection of several channel from different layers to preamplifier channel (tower) Direct connection of several channel from different layers to preamplifier channel (tower) Three pads have been connected to one channel (will be 6) Three pads have been connected to one channel (will be 6) Total load capacitance ~200 pF Total load capacitance ~200 pF This is almost limit for CR-1.4 This is almost limit for CR-1.4 What we have tested?

6/5/06 14 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Test run at U-70 IHEP, Protvino 70 GeV protons 70 GeV protons 10 GeV positrons 10 GeV positrons

6/5/06 15 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin MIP resolution Amplitude distribution for MIP (μ, p)

6/5/06 16 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Longitudinal e + shower profile

6/5/06 17 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Energy resolution for 10 GeV e +. Full amplitude sum for all layers ~11%

6/5/06 18 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Picture of Positron Event #17 Run 39

6/5/06 19 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin

6/5/06 20 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin Picture of Positron Event #29 Run 39

6/5/06 21 CALOR06: "Performance of the PHENIX NCC Prototype", Michael Merkin