AXEL-2009 Introduction to Particle Accelerators

1. AXEL-2009Introduction to Particle Accelerators Longitudinal motion: The basic synchrotron equations. What is Transition ? RF systems. Motion of low & high energy particles. Acceleration. What are Adiabatic changes? Rende Steerenberg (BE/OP) 21 January 2009

2. But Change in orbit length Change in velocity Momentum compaction factor Therefore: Motion in longitudinal plane • What happens when particle momentum increases? particles follow longer orbit (fixed B field)  particles travel faster (initially) • How does the revolution frequency change with the momentum ? AXEL - 2009

3. But The frequency - momentum relation • The relativity theory says  varies with momentum (E = E0) fixed by the lattice AXEL - 2009

4. Transition • Lets look at the behaviour of a particle in a constant magnetic field. • Low momentum ( << 1,   1) • The revolution frequency increases as momentum increases • High momentum (  1,  >> 1) • The revolution frequency decreases as momentum increases • For one particular momentum or energy we have: • This particular energy is called the Transition energy AXEL - 2009

5.   = positive Below transition  = zero Transition  = negative Above transition The frequency slip factor • We found • Transition is very important in proton machines. • A little later we will see why…. • In the PS machine :tr is at ~6 GeV/c • In the LHC machine : :tr is at ~55 GeV/c • Transition does not exist in leptons machines, why? AXEL - 2009

6. Radio Frequency System • Hadron machines: • Accelerate / Decelerate beams • Beam shaping • Beam measurements • Increase luminosity in hadron colliders • Lepton machines: • Accelerate beams • Compensate for energy loss due to synchrotron radiation. (see lecture on Synchrotron Radiation) AXEL - 2009

7. Particles V volts RF Cavity • To accelerate charged particles we need a longitudinal electric field. • Magnetic fields deflect particles, but do not accelerate them. Vacuum chamber Insulator (ceramic) • If the voltage is DC then there is no acceleration ! • The particle will accelerate towards the gap but decelerate after the gap. • Use an Oscillating Voltage with the right Frequency AXEL - 2009

8. V V time 1st revolution period 2nd revolution period A Single particle in a longitudinal electric field • Lets see what a low energy particle does with this oscillating voltage in the cavity. • Set the oscillation frequency so that the period is exactly equal to one revolution period of the particle. AXEL - 2009

9. V A A V time B B • B arrives late in the cavity w.r.t. A • B sees a higher voltage than A and will therefore be accelerated 1st revolution period ~ 20th revolution period • After many turns B approaches A • B is still late in the cavity w.r.t. A • B still sees a higher voltage and is still being accelerated Add a second particle to the first one • Lets see what a second low energy particle, which arrives later in the cavity, does with respect to our first particle. AXEL - 2009

10. Lets see what happens after many turns V A time B 1st revolution period AXEL - 2009

11. Lets see what happens after many turns V A time B 100st revolution period AXEL - 2009

12. Lets see what happens after many turns V A time B 200st revolution period AXEL - 2009

13. Lets see what happens after many turns V A time B 400st revolution period AXEL - 2009

14. Lets see what happens after many turns V A time B 500st revolution period AXEL - 2009

15. Lets see what happens after many turns V A time B 600st revolution period AXEL - 2009

16. Lets see what happens after many turns V A time B 700st revolution period AXEL - 2009

17. Lets see what happens after many turns V A time B 800st revolution period AXEL - 2009

18. Lets see what happens after many turns V A time B 900st revolution period AXEL - 2009

19. V A time B 900st revolution period Synchrotron Oscillations • Particle B has made 1 full oscillation around particle A. • The amplitude depends on the initial phase. • We call this oscillation: Exactly like the pendulum Synchrotron Oscillation AXEL - 2009

20. A Cavity voltage Potential well B The Potential Well (1) AXEL - 2009

21. A Cavity voltage Potential well B The Potential Well (2) AXEL - 2009

22. A Cavity voltage Potential well B The Potential Well (3) AXEL - 2009

23. A Cavity voltage Potential well B The Potential Well (4) AXEL - 2009

24. A Cavity voltage Potential well B The Potential Well (5) AXEL - 2009

25. A Cavity voltage Potential well B The Potential Well (6) AXEL - 2009

26. A Cavity voltage Potential well B The Potential Well (7) AXEL - 2009

27. A Cavity voltage Potential well B The Potential Well (8) AXEL - 2009

28. A Cavity voltage Potential well B The Potential Well (9) AXEL - 2009

29. A Cavity voltage Potential well B The Potential Well (10) AXEL - 2009

30. A Cavity voltage Potential well B The Potential Well (11) AXEL - 2009

31. A Cavity voltage Potential well B The Potential Well (12) AXEL - 2009

32. A Cavity voltage Potential well B The Potential Well (13) AXEL - 2009

33. A Cavity voltage Potential well B The Potential Well (14) AXEL - 2009

34. A Cavity voltage Potential well B The Potential Well (15) AXEL - 2009

35. E t (or ) Longitudinal Phase Space • In order to be able to visualize the motion in the longitudinal plane we define the longitudinal phase space (like we did for the transverse phase space) AXEL - 2009

36. E t (or ) Phase Space motion (1) • Particle B oscillates around particle A • This is synchrotron oscillation • When we plot this motion in our longitudinal phase space we get: higher energy early arrival late arrival lower energy AXEL - 2009

37. E t (or ) Phase Space motion (2) • Particle B oscillates around particle A • This is synchrotron oscillation • When we plot this motion in our longitudinal phase space we get: higher energy early arrival late arrival lower energy AXEL - 2009

38. E t (or ) Phase Space motion (3) • Particle B oscillates around particle A • This is synchrotron oscillation • When we plot this motion in our longitudinal phase space we get: higher energy early arrival late arrival lower energy AXEL - 2009

39. E t (or ) Phase Space motion (4) • Particle B oscillates around particle A • This is synchrotron oscillation • When we plot this motion in our longitudinal phase space we get: higher energy early arrival late arrival lower energy AXEL - 2009

40. Quick intermediate summary… • We have seen that: • The RF system forms a potential well in which the particles oscillate (synchrotron oscillation). • We can describe this motion in the longitudinal phase space (energy versus time or phase). • This works for particles below transition. • However, • Due to the shape of the potential well, the oscillation is a non-linear motion. • The phase space trajectories are therefore no circles nor ellipses. • What when our particles are above transition ? AXEL - 2009

41. E E t (or ) t Stationary bunch & bucket Bunch • Bucket area = longitudinal Acceptance [eVs] • Bunch area = longitudinal beam emittance =.E.t/4 [eVs] Bucket AXEL - 2009

42. E E t (or ) T = revolution time Unbunched (coasting) beam • The emittance of an unbunched beam is just ET eVs • E is the energy spread [eV] • T is the revolution time [s] AXEL - 2009

43. Higher energy  faster orbit higher Frev  next time particle will be earlier. Lower energy  slower orbit lower Frev  next time particle will be later. Higher energy  longer orbit lower Frev  next time particle will be later. Lower energy  shorter orbit higher Frev  next time particle will be earlier. What happens beyond transition ? • Until now we have seen how things look like below transition  = positive • What will happen above transition ?  = negative AXEL - 2009

44. What are the implication for the RF ? • For particles below transition we worked on the rising edge of the sine wave. • For Particles above transition we will work on the falling edge of the sine wave. • We will see why…….. AXEL - 2009

45. RF Voltage E V A time B decelerating Longitudinal motion beyond transition (1) accelerating • Imagine two particles A and B, that arrive at the same time in the accelerating cavity (when Vrf = 0V) • For A the energy is such that Frev A = Frf. • The energy of B is higher  Frev B < Frev A AXEL - 2009

46. accelerating RF Voltage E V A B decelerating Longitudinal motion beyond transition (2) • Particle B arrives after A and experiences a decelerating voltage. • The energy of B is still higher, but less Frev B < Frev A time AXEL - 2009

47. accelerating RF Voltage E V A time B decelerating Longitudinal motion beyond transition (3) • B has now the same energy as A, but arrives still later and experiences therefore a decelerating voltage. • Frev B = Frev A AXEL - 2009

48. accelerating RF Voltage E V A time B decelerating Longitudinal motion beyond transition (4) • Particle B has now a lower energy as A, but arrives at the same time • Frev B > Frev A AXEL - 2009

49. accelerating RF Voltage E V A time B decelerating Longitudinal motion beyond transition (5) • Particle B has now a lower energy as A, but B arrives before A and experiences an accelerating voltage. • Frev B > Frev A AXEL - 2009

50. accelerating RF Voltage E V A time B decelerating Longitudinal motion beyond transition (6) • Particle B has now the same energy as A, but B still arrives before A and experiences an accelerating voltage. • Frev B > Frev A AXEL - 2009