1. Physics of Particle Accelerators Kalanand Mishra Department of Physics University of Cincinnati

2. How a Particle Accelerator Works Speed up particle with E/M field Smash particles into target or other particles Record collisions with detectors Able to identify product particles

3. Physics of a Particle Accelerator  Beam production  Bunching  Electron guns  Beam focusing  Colliding and Detecting

4. Beam production Electron Beam Thermoionic Emission

5. Ionizing Hydrogen Glow Discharge Column From H - Ion Proton Beam

6. Other Beams Secondary Beams: Proton Antiproton Other Particle Beams

7. Bunching Bring the Particles in phase. As spread out beam gives fewer collisions than a narrowly focused one, e - & e + bunches are sent into damping rings (e - to north, e + to south).

8. Colliding Fixed target E =  (2mE p ) Colliding beam E = 2E p

9. Beam Focusing  As spread out beam gives fewer collisions than a narrowly focused one, e - & e + beams have to be focused.  This is done by bent magnets.

10. Two Types Linear Path Travel once Circular Path Travel several times

11. Linear Accelerator

12. LINAC Operation

13. Methods of Acceleration in Linear Accelerator SLC Polarized Electron Gun

14. Methods of Acceleration in Linear Accelerator Basic idea Synchronization Length of the tube Shielding

15. LINAC cont’d Klystron: Microwave generator 1. Electron gun produces a flow of electrons. 2. Bunching cavities regulate speed of electrons so that bunches arrive at the output cavity. 3. Bunches of electrons excite microwaves in output cavity of the klystron. 4. Microwaves flow into the waveguide, which transports them to the accelerator. 5. Electrons are absorbed in beam stop.

16. Overall Operation of LINAC Electrons are Accelerated in a Copper Structure Bunches of electrons are accelerated in the copper structure of the linac in much the same way as a surfer is pushed along by a wave. Changing Electric and Magnetic Fields:

17. E/M waves that push the electrons in the linac are created by higher energy versions of the microwaves used in the microwave ovens in our kitchens. The microwaves from the klystrons in the Klystron Gallery are fed into the accelerator via waveguides. This creates a pattern of E&B fields, which form an E/M wave traveling down the accelerator. Klystron Operation

18. The 2-mile SLAC linear accelerator (linac) is made from over 80,000 copper discs and cylinders brazed together. LINAC Structure  Microwaves set up currents that cause E pointing along accelerator and B in a circle around interior of accelerator.  Want e - and e + to arrive in each cavity at right time to get max. push from E.  e + needs to arrive when field polarity is opposite.

19. Circular Accelerator

20. Methods of Acceleration in Circular Accelerator Cyclotron The Ds Electric field across the gap Circular orbit Increasing radius

21. Cyclotron The maximum speed a proton could have in a dee of radius R and strength B is given by (ignoring relativistic effects.) v m = BeR / m p

22. Synchrotron (synchro-cyclotron) Methods of Acceleration in Circular Accelerator Electromagnetic resonant cavity Magnetic field for circular orbit Field synchronization with increasing particle energy Synchrotron radiation Storage ring

23. Synchrotron The radius of curvature of the path of particles of momentum p and charge q in a synchrotron is given by the formula R = p / q B where B is the field strength. If a synchrotron of radius R has 4 straight sections of length L each and period of the radio frequency oscillator corresponds to the time of one revolution then (a) The speed of the particles is v = ( 2pR + 4L ) f

24. Synchrotron (b) By considering the relativistic momentum of particles of mass M, the magnetic field strength of the synchrotron is given by where f is the frequency.

25. Storage Rings Similar to a synchrotron, but designed to keep particles circulating at const. energy not increase energy further SPEAR : 3 GeV PEP I : 9 GeV PEP II : e - 9 GeV e + 3.1 GeV

26. Detection Tracking bubble, radiation Tracking curvature (charged particle)