1. Detectors & Measurements: How we do physics without seeing… Prof. Robin D. Erbacher University of California, Davis References: R. Fernow, Introduction to Experimental Particle Physics, Ch. 14, 15 D. Green, The Physics of Particle Detectors, Ch. 13 http://pdg.lbl.gov/2004/reviews/pardetrpp.pdf Lectures from CERN, Erbacher, Conway, … Overview of Detectors and Fundamental Measurements: From Quarks to Lifetimes

2. The Standard Model The SM states that: The world is made up of quarks and leptons that interact by exchanging bosons. Lepton Masses: M e <M  <M  M ~0.* Quark Masses: M u ~ M d < M s < M c < M b << M t A Higgs field interacts as well, giving particles their masses. 35 times heavier than b quark

3. Idealistic View: Elementary Particle Reaction  Usually cannot “see” the reaction itself  To reconstruct the process and the particle properties, need maximum information about end-products Particle Reactions Time

4. Complicated Collisions

5. Rare Collision Events Time Rare Events, such as Higgs production, are difficult to find! Need good detectors, triggers, readout to reconstruct the mess into a piece of physics. Cartoon by Claus Grupen, University of Seigen

6. We don’t use bubble chambers anymore!

7. Overall Design Depends on: – Number of particles – Event topology – Momentum/energy – Particle identity Global Detector Systems Fixed Target Geometry Collider Geometry Limited solid angle (d  coverage (forward) Easy access (cables, maintenance) “full” solid angle d  coverage Very restricted access  No single detector does it all…  Create detector systems

8. Ideal Detectors An “ideal” particle detector would provide… Coverage of full solid angle, no cracks, fine segmentation (why?) Measurement of momentum and energy Detection, tracking, and identification of all particles (mass, charge) Fast response: no dead time (what is dead time?) However, practical limitations: Technology, Space, Budget End products

9. Individual Detector Types Modern detectors consist of many different pieces of equipment to measure different aspects of an event. Measuring a particle’s properties: Ô Position Ô Momentum Ô Energy Ô Charge Ô Type

10. Particle Decay Signatures Particles are detected via their interaction with matter. Many types of interactions are involved, mainly electromagnetic. In the end, always rely on ionization and excitation of matter.

11. “Jets” Jet (jet) n. a collimated spray of high energy hadrons Quarks fragment into many particles to form a jet, depositing energy in both calorimeters. Jet shapes narrower at high E T.

12. Modern Collider Detectors the basic idea is to measure charged particles, photons, jets, missing energy accurately want as little material in the middle to avoid multiple scattering cylinder wins out over sphere for obvious reasons!

13. CDF Top Pair Event b quark jets missing E T q jet 1 q jet 2 high p T muon b-quark lifetime: c  ~ 450  m  b quarks travel ~3 mm before decay

14. CDF Top Pair Event

15. Particle Detection Methods Signature Detector Type Particle Jet of hadrons Calorimeter u, c, t  Wb, d, s, b, g ‘Missing’ energy Calorimeter e, ,  Electromagnetic shower, X o EM Calorimeter e, , W  e Purely ionization interactions, dE/dx Muon Absorber ,  Decays,c  ≥ 100  m Si tracking c, b, 

16. Aleph at LEP (CERN)

17. Particle Identification Methods Constituent Si Vertex Track PID Ecal Hcal Muon PID = Particle ID (TOF, C, dE/dx) v electron primary    — — Photon  primary — —  — — u, d, gluon primary  —   — Neutrino  — — — — — — s primary     — c, b,  secondary     —  primary  — MIP MIP  MIP = Minimum Ionizing Particle

18. Quiz: Decays of a Z boson Z bosons have a very short lifetime, decaying in ~10 -27 s, so that only decay particles are seen in the detector. By looking at these detector signatures, identify the daughters of the Z boson. More Fun with Z Bosons, Click Here! But some daughters can also decay:

19. CDF Schematic

20. Geometry of CDF calorimeter is arranged in projective “towers” pointing at the interaction region most of the depth is for the hadronic part of the calorimeter

21. CDF Run 2 Detector New Endplug Calorimeter Endwall Calorimeter Central Outer Tracker Silicon Vertex Detector

22. QCD Di-Jet Event, Calorimeter Unfolded Central/Plug Di-Jet

23. Unfolded Top/anti-Top Candidate Run 1 Event

24. Unfolded Top/anti-Top Candidate Run 2 Event

25. Call ‘em Spectrometers a “spectrometer” is a tool to measure the momentum spectrum of a particle in general one needs a magnet, and tracking detectors to determine momentum: helical trajectory deviates due to radiation E losses, spatial inhomogeneities in B field, multiple scattering, ionization Approximately:

26. Magnets for 4  Detectors SolenoidToroid + Large homogeneous field inside - Weak opposite field in return yoke - Size limited by cost - Relatively large material budget + Field always perpendicular to p + Rel. large fields over large volume + Rel. low material budget - Non-uniform field - Complex structural design Examples: Delphi: SC, 1.2 T, 5.2 m, L 7.4 m L3: NC, 0.5 T, 11.9 m, L 11.9 m CMS: SC, 4 T, 5.9 m, L 12.5 m Example: ATLAS: Barrel air toroid, SC, ~1 T, 9.4 m, L 24.3 m

27. Charge and Momentum Two ATLAS toroid coils Superconducting CMS Solenoid Design

28. Charge and Momentum

29. CMS at CERN S = Solenoid!

30. CMS Muon Chambers

31. CMS Spectrometer Details 12,500 tons (steel, mostly, for the magnetic return and hadron calorimeter) 4 T solenoid magnet 10,000,000 channels of silicon tracking (no gas) lead-tungstate electromagnetic calorimeter 4π muon coverage 25-nsec bunch crossing time 10 Mrad radiation dose to inner detectors...

32. CMS: All Silicon Tracker All silicon: pixels and strips! 210 m 2 silicon sensors 6,136 thin detectors (1 sensor) 9,096 thick detectors (2 sensors) 9,648,128 electronics channels

33. Possible Future at the ILC: SiD All silicon sensors: pixel/strip tracking “imaging” calorimeter using tungsten with Si wafers

34. Fixed Target Spectrometers Coming next time…