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PHYS 3446 – Lecture #17 Particle Detection Particle Accelerators

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1 PHYS 3446 – Lecture #17 Particle Detection Particle Accelerators
Monday, Oct. 31, 2016 Dr. Jae Yu Particle Detection Semi-Conductor Detectors Calorimeters Particle Accelerators Electro-static Accelerators Cyclotron Accelerators Synchrotron Accelerators Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

2 Announcements Quiz #2 result
Class average: 28.6/66 Equivalent to: 43.3/100 Previous result: 47.1/100 Top score: 65/66 Mark on your calendar two special colloquia – double extra credit: Nov. 30: Dr. Steven Sand Dec. 7: Dr. K.C.Kong Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

3 Homework #8 Carry out Fourier transformation and derive equations 9.3 and 9.5 Due for these assignments is Monday, Nov. 7 Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

4 Semiconductor Detectors
Semiconductors can produce large signal (electron-hole pairs) for a relatively small energy deposit (~3eV) Advantageous in measuring low energy at high resolution Silicon strip and pixel detectors are widely used for high precision position measurements Due to large electron-hole pair production, thin layers (200 – 300 mm) of wafers are sufficient for measurements Output signal proportional to the ionization loss in the semiconductor Low bias voltages sufficient to operate Can be deposit in thin stripes (20 – 50 mm) on a thin electrode High position resolution achievable Can be used to distinguish particles in multiple detector configurations So what is the catch? Very expensive  On the order of $30k/m2 Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

5 DØ Silicon Vertex Detector
2 3 4 9 8 11 1 6 7 5 10 12 …... One Si detector Disk Barrel Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

6 Calorimeters Magnetic measurement of momentum is not sufficient for physics, why? The precision for angular measurements gets worse as particles’ momenta increases Increasing the magnetic field or increasing the precision of the tracking device will help but will be expensive Cannot measure neutral particle momenta How do we solve this problem? Use a device that measures kinetic energies of the particle Calorimeter A device that absorbs the full kinetic energy of the particle Provides signal proportional to deposited energy Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

7 Calorimeters Large scale calorimeter were developed during 1960s
For energetic cosmic rays For particles produced in accelerator experiments How do high energy EM (photons and electrons) and Hadronic particles deposit their energies? Electrons: via bremsstrahlung Photons: via electron-positron conversion, followed by bremsstrahlung of electrons and positrons These processes continue occurring in the secondary particles causing an electromagnetic shower losing all of its energy Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

8 Electron Shower Process
Photon, g Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

9 Calorimeters Hadrons are massive thus their energy deposit via brem is small They lose their energies through multiple nuclear collisions An incident hadron produces multiple pions and other secondary hadrons in the first collision with a nucleus The secondary hadrons then successively undergo nuclear collisions Mean free path for nuclear collisions is called nuclear interaction lengths or nuclear absorption length (l0abs) and is substantially longer than that of EM particles, radiation length (X0) Hadronic shower processes are therefore more erratic than EM shower processes Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

10 Sampling Calorimeters
High energy particles require large calorimeters to absorb all of their energies and measure them fully in the device (called total absorption calorimeters) The number of shower particles is directly proportional to the energy of the incident particles One can deduce the total energy of the particle by measuring only the fraction of their energy, as long as the fraction is known  Called sampling calorimeters Most the high energy experiments use sampling calorimeters Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

11 ATLAS LAr EM Calorimeter
Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

12 How particle showers look in a detector
Hadron EM Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

13 A fresh new event at the ATLAS
Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

14 Principles of Calorimeters
Total absorption calorimeter: Sees the entire shower energy, all active volume! Sampling calorimeter: Sees only some fraction of the shower energy For EM For HAD Absorber plates Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

15 Example Hadronic Shower (20GeV)
Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

16 DØ Central Calorimeter 1990
Monday, Oct. 31, 2016 PHYS 3446, Fall 2016

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