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Basic of Detector

Basic of Detector. Atsushi Taketani 竹谷篤 RIKEN Nishina Center Detector Team RIKEN Brookhaven Research Center. What I worked for detectors. Electron-Positron collider Experiment at 60GeV Trigger electronics, TRD, EMCAL, Si Sensor Proton-Antiproton collider experiment at 1.8TeV

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Basic of Detector

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  1. Basic of Detector Atsushi Taketani 竹谷篤 RIKEN Nishina Center Detector Team RIKEN Brookhaven Research Center

  2. What I worked for detectors • Electron-Positron collider Experiment at 60GeV • Trigger electronics, TRD, EMCAL, Si Sensor • Proton-Antiproton collider experiment at 1.8TeV • Muon detector, Readout electrinics • Large scale Accelerator control at 8GeV • Distributed computing system hardware/software • Polarize proton-proton/ Heavy Ion collider experiment at 200GeV • Muon detector, Si detector • Start to work for Detectors for RIBF experiment Working higher energy

  3. Index of this lecture • Why/How we need detector? • What do we want to measure? • Gas Chamber basics • Scintillator • PHENIX experiment and Silicon Detector • Summary

  4. Importance of Detector Physics detector Human • We need detector to understand physics • Detector innovation can arise new physics • Telescope (1590) : Newton mechanics(Late 1600’s) • Velocity of light measurement (1873): Relativity (1905, 1916) • High resolution hydrogen spectroscopy : Quantum mechanics ( 1925)

  5. Major Detector Principle • Particle penetrates or stops at detector • Particle interacts with material of detector • Generating some signal • Amplification mechanism • Analog to Digital conversion • Getting into computer • Analyze at digital data ->physics PC Digital signal Amp. Analog to digital conversion Sensor Particle electric signal (analog) Data taking Scintillator Semiconductor Detectors Coaxial cable

  6. Particle mass • Particle has its own mass. • electron 0.511MeV • m 105MeV • p+, p- 140MeV, p0 135MeV • Proton 928MeV • J/y 3069MeV (discovered by S.C.C. Ting and B. Richter) • Top quark 172GeV (heaviest particle ever observed) • If we know the mass of particle, we can identify the particle species.

  7. 4-momentum • Treating the mass at relativity P2 = E2 - | p|2 = m2 Where P : 4-momentum E : Energy p : 3-momentum ( px, py, pz ) m : invariant mass

  8. 4-momentum • (E, px, py, pz ) • Invariant mass : m2 = E2 - | p|2 • 3-momentum (velocity) v/c = b = p/E Where c is light velocity • If we can measure 3-momentum p, and Energy E or 3-momentum b, m can be obtained -> identifying particle.

  9. 3-momentum measurement • Momentum can be measured by using Lorentz force F: force, q: electric charge, E: electric field v: particle velocity = p/m, B: magnetic field Constant force -> Constant curvature -> particle track trajectory P [MeV/c] = 3 * r[cm] * B[T] r: curvature radius, B: magnetic field

  10. Energy measurement • Particle stops at the material and measure all deposited energy by energy loss • b = p/E : particle velocity measure timing deference between 2 known location Calorimeter Energy(value) particle L b = V/c = L/(t2-t1)/c particle t2 t1

  11. Particle and material interaction • Particle will hit, penetrate, or stop at material, including gas, liquid, solid. • Particle has some interaction with material, then we can detect it. -> Detector • Energy Loss, Multiple Scattering and So.

  12. Energy Loss and stopping power 5.49MeV a particle in air electric Energy loss [MeV/cm] Energy loss [MeV/cm] nuclear Particle energy [MeV] Path length [cm]

  13. Particle charge Bethe-Bloch formula Energy loss [MeV cm2/g] Particle energy [MeV]

  14. Particle energy [MeV] Typical Energy Loss • dE/dX ~ 1MeV cm2/g for Minimum ionizing particle • Energy loss / Unit length ~ 2MeV cm2/g * Material density [g/cm3] For example at Al dE/dX = 1.615MeV cm2/g Aluminum r=2.70g/cm3 Energy loss =0.60MeV/cm Minimum Ionizing Particle

  15. Multiple Scattering for M.I.P. Z: particle charge x: material thickness X0: radiation length

  16. Atomic and Nuclear properties of materials

  17. Example • Aluminum 1cm thickness with electron 50MeV • Estimate the angle deviation at exit, ignore energy loss. • Radiation length X0=24.01 [g/cm2] / 2.699[g/cm3]=8.9[cm] x/X0=0.11

  18. Typical Wire Chamber

  19. Gas Chamber • Energetic particle passing through gas. • Gas molecules are ionized -> electrons and ions. • Electrons and ions are drifted to electro load with minus and plus voltage • Avalanche near by wire • Getting electrical signal

  20. - + Ionization • Ionization happens along charged particle track • #Electorn-Ion pair/unit length = dE/dX / Pair creation energy • Pair creation Energy • H2 37eV • Ar 26eV - + - + - + - + - + - + Gas Chamber

  21. Ionization Ar: dE/dX = 1.519MeV cm2/g electron-ion = 97 /cm density = 1.662 g/L pair creation energy = 26 eV #electron-ion = 1.519MeV cm2/g * 106 eV/MeV * 1.662g/l*1000cm3/l /26eV = 97 /cm

  22. Drift drift velocity =50~100mm/nsec = 5mm~10mm / 100 nsec Drift velocity[mm/nsec] Electric field and potential Electric field [KV/cm]

  23. Avalanche E: electric field r: distance from wire V0: bias voltage a: radius of cylinder b: wire radius electron Electric filed gas molecule Gas multiplication

  24. Gas Gain a/Pressure Multiplication Electric field/Pressure [V/cm /mmHg] Voltage [V]

  25. Magnetic filed Measurement of the momentum P [MeV/c] = 3 * r[cm] * B[T] r: curvature radius, B: magnetic field

  26. Photo Multiplier Tube

  27. Precise Time measurement detector Plastic scintillator • Charged particle is penetrating • Lower energy electron is exited to upper state • Upper state electron drops into lower state and emits a photon • Propagate to P.M.T. • P.M.T. generates electric pulse. Charged particle Light guide Photo Multiplier Tube Timing pulse

  28. Electric pulse ~ particle energy electron electron/positron P.M.T. NaI Crystal g Calorimeter Mass of electron is 511KeV g->e++e- for Eg>1.02MeV

  29. Typical Detector System Magnetic field L: length Calorimeter Energy =E Wire Chambers Scitillator Timing =t2 Scitillator Timing = t1 P [MeV/c] = 3 * r[cm] * B[T] r: curvature radius, B: magnetic field b = V/c = L/(t2-t1)/c E=P/b m2=E2+P2 Determine 4-momentum

  30. Other Major Detectors (include past) Detector dead time after a hit Position sensitivity Timing sensitivity

  31. VTX will be installed into inner most detector from beam pipe PHENIX Where is VTX VTX p, Au • Good particle ID • High resolution • High trigger rate p, Au

  32. Summary • We need to have detector to investigate nature since you can not feel particles. • You have to build and/or be familiar with detector for your own experiments.

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