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Laser-based Beam Diagnostics for the RAL Front End Test Stand

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Presentation on theme: "Laser-based Beam Diagnostics for the RAL Front End Test Stand"— Presentation transcript:

1 Laser-based Beam Diagnostics for the RAL Front End Test Stand
Thanks for the introduction Grateful to Jon and the group for opportunity to give this seminar Going to be talking about… David Lee

2 Outline The Front End Test Stand (FETS) Beam diagnostics
Beam profile measurements Non-intrusive beam diagnostics Laser-based H− diagnostics FETS laser profile monitor Conclusion First I’ll introduce the FETS Then I’ll talk a bit about beam diagnostics, motivating the need for non-intrusive beam diagnostics and describing how that can be done using lasers for H− beams And go on to describe the design and status of the FETS laser profile measuring device Laser-based Beam Diagnostics for the RAL Front End Test Stand • 1

3 The Front End Test Stand
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 2 David Lee • 28/01/2009

4 The Front End Test Stand
Beam dump and laser emittance measurement upstream (not shown) MEBT and chopper RFQ Magnetic LEBT H− ion source Test Stand for first part (the Front End) of next-generation proton accelerator chain – beam quality (emittance) defined here. Mention losses (context of ISIS losses?) Give context (what can be used for) Describe components briefly Ion source H− (injection into ring) 65 keV 60 mA 2 ms LEBT Low Energy Beam Transport 3 Solenoids Matches RFQ Bunches and Accelerates whilst constantly focussing MEBT Matches the beam from the RFQ to the downstream linac Chopper Removes some bunches to minimise injection losses Laserwire Mention! Laser profile monitor Laser-based Beam Diagnostics for the RAL Front End Test Stand • 3

5 Neutrino Factory Laser-based Beam Diagnostics for the RAL Front End Test Stand • 4

6 Neutrino Factory Laser-based Beam Diagnostics for the RAL Front End Test Stand • 4

7 Status Laser-based Beam Diagnostics for the RAL Front End Test Stand • 5

8 Status MENTION Time frame for first ion beam
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 5

9 Status Laser-based Beam Diagnostics for the RAL Front End Test Stand • 5

10 Status Laser-based Beam Diagnostics for the RAL Front End Test Stand • 5

11 Beam Diagnostics Laser-based Beam Diagnostics for the RAL Front End Test Stand • 6 David Lee • 28/01/2009

12 Beam Profile Measurements
Why are beam profile measurements of interest? First half of the beam emittance Gives information about the charge density And so the beam’s self field / space charge Will the beam fit through the beam pipe? What is the beam halo like? How are they typically done? Scintillator Wire scanner EXPLAIN What you mean by profile and projection NEXT Non-intrusive beam diagnostics Laser-based Beam Diagnostics for the RAL Front End Test Stand • 7

13 Non-intrusive diagnostics
Allows for online monitoring of the beam Keeps users happy MENTION Scintillator Example Laser-based Beam Diagnostics for the RAL Front End Test Stand • 8

14 Non-intrusive diagnostics
Allows for online monitoring of the beam Keeps users happy Beam dynamics not affected by the instrument Keeps accelerator group happy Residual gas ion energy analyser RGIE spectrum (beam potential distribution) depending on position of emittance scanner Ion source ~10 keV dc Helium beam Beam potential affects space charge and so the beam dynamics dl’ / dW [μA / (eV m)] 200V 0.365T 0V 0.406T Allison scanner in / out Beam dump 0V W / eV Laser-based Beam Diagnostics for the RAL Front End Test Stand • 8

15 Non-intrusive diagnostics
Allows for online monitoring of the beam Keeps users happy Beam dynamics not affected by the instrument Prevents the beam from damaging the instrument Keeps accelerator group happy Plastic Ruby P46 MENTION Activation (particularly above ~3 MeV) NEXT Laser-based H− diagnostics Laser-based Beam Diagnostics for the RAL Front End Test Stand • 8

16 Ionisation Cross Section
MENTION Outer electron loosely bound ~0.75 eV (inner electron ~13.6 eV) MENTION Non-relativistic (no Doppler shift) Laser-based Beam Diagnostics for the RAL Front End Test Stand • 9

17 Ionisation Cross Section
MENTION Negligible momentum transfer to electrons MENTION Laser parameters Laser-based Beam Diagnostics for the RAL Front End Test Stand • 9

18 Laser-based H− diagnostics
To measure Beam profiles Longitudinal emittances use photo-detached electrons What do we do once the electron is detached? Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

19 Laser-based H− diagnostics
To measure Beam profiles Longitudinal emittances use photo-detached electrons Collect the detached electrons MENTION Number of electrons detached MENTION How do longitudinal emittance Photo-ionise some of the H- ions Separate species using a dipole magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

20 Laser-based H− diagnostics
Collect the detached electrons Photo-ionise some of the H- ions Separate species using a dipole magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

21 Laser-based H− diagnostics
Collect the detached electrons Photo-ionise some of the H- ions Separate species using a dipole magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

22 Laser-based H− diagnostics
Collect the detached electrons Photo-ionise some of the H- ions Separate species using a dipole magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

23 Laser-based H− diagnostics
Collect the detached electrons Photo-ionise some of the H- ions Separate species using a dipole magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

24 Laser-based H− diagnostics
Collect the detached electrons Photo-ionise some of the H- ions Separate species using a dipole magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 10

25 Laser-based H− diagnostics
To measure Transverse emittances use photo-ionised neutrals Laser-based Beam Diagnostics for the RAL Front End Test Stand • 11

26 Laser-based H− diagnostics
To measure Transverse emittances use photo-ionised neutrals Use a dipole to separate out the particles neutralised by residual gas interactions Laser-based Beam Diagnostics for the RAL Front End Test Stand • 11

27 Laser-based H− diagnostics
To measure Transverse emittances use photo-ionised neutrals Photo-ionised neutrals Photo-ionise some of the H- ions in the dipole Residual gas neutrals Laser-based Beam Diagnostics for the RAL Front End Test Stand • 11

28 Laser-based H− diagnostics
To measure Transverse emittances use photo-ionised neutrals Image with scintillator and CCD CCD Photo-ionised neutrals Photo-ionise some of the H- ions in the dipole Residual gas neutrals Laser-based Beam Diagnostics for the RAL Front End Test Stand • 11

29 Laser-based H− diagnostics
Image with scintillator and CCD CCD Photo-ionised neutrals MENTION Scan laser across to get (eg.) y information (Can also be clever and extract x-x’ information too) Photo-ionise some of the H- ions in the dipole Residual gas neutrals Laser-based Beam Diagnostics for the RAL Front End Test Stand • 11

30 The Front End Test Stand Laser Profile Monitor
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 12 David Lee • 28/01/2009

31 The Benefit of Multiple (>2) Projections
Before describing the device itself I’d like to motivate one of it’s design features: namely, the ability to measure more than 2 (x and y) projections of the beam Laser-based Beam Diagnostics for the RAL Front End Test Stand • 13 David Lee • 28/01/2009

32 The Benefit of Multiple (>2) Projections
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 13

33 The Benefit of Multiple (>2) Projections
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 13

34 The Benefit of Multiple (>2) Projections
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 13

35 Laser-scanning setup To get multiple projections, need to be able to pass laser through beam at variety of angles To do this, use movable mirrors mounted in vacuum vessel Laser-based Beam Diagnostics for the RAL Front End Test Stand • 14

36 Laser-scanning setup MENTION longitudinal length of vacuum vessel
MENTION Start with only x-motors Laser-based Beam Diagnostics for the RAL Front End Test Stand • 15

37 Laser-scanning setup MENTION Mirror location
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 15

38 Optics A simple, one lens setup will be used to begin with
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 16

39 Optics MENTION 0.09% difference in laser beam size at edge of ion beam compared to centre NEXT Detector Laser-based Beam Diagnostics for the RAL Front End Test Stand • 17

40 Copper accelerating sheath
The Detector Faraday Cup Electrons Magnet H−, H0 EXPLAIN Copper sheath and Mention range of detector – up to hundreds (~350) of MeV. MENTION Holes are for pumping Copper accelerating sheath Laser-based Beam Diagnostics for the RAL Front End Test Stand • 18

41 The Detector Constructed here in the workshop
Compact; the whole assembly is ~80x100x250 mm Beam direction NEXT Simulation Laser-based Beam Diagnostics for the RAL Front End Test Stand • 19

42 Simulations Detector’s E and B fields simulated using a electromagnetic finite element program CST EM Studio Particle tracking was performed by the General Particle Tracer package Input distribution from a pepperpot correlated emittance measurement of the ion source Laser-based Beam Diagnostics for the RAL Front End Test Stand • 20

43 Simulations Faraday Cup Magnet yoke Copper accelerating sheath
Cross section through detector Electron Trajectories are in black Coloured lines are isopotential Copper accelerating sheath Laser-based Beam Diagnostics for the RAL Front End Test Stand • 21

44 Dipole Field Map To confirm the simulation results the dipole had its field (bending component; By) mapped MENTION Daresbury Laser-based Beam Diagnostics for the RAL Front End Test Stand • 22

45 Dipole Field Map MENTION Results include hysteresis
NEXT Longitudinal acceptance Laser-based Beam Diagnostics for the RAL Front End Test Stand • 23

46 Dipole Field Map EXPLAIN Good agreement between results and simulation, particularly in key central region MENTION Larger discrepancies near the pole pieces go to ~6%. Not too bothered due to location of plane Laser-based Beam Diagnostics for the RAL Front End Test Stand • 24

47 Longitudinal Acceptance
Electrons from residual gas interactions form a background to our measurement Problem made worse by proximity to ion source 20 ml per minute of hydrogen gas To reduce this background, the longitudinal acceptance of the detector can be reduced by introducing an additional electrode Laser-based Beam Diagnostics for the RAL Front End Test Stand • 25

48 Longitudinal Acceptance
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

49 Longitudinal Acceptance
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

50 Longitudinal Acceptance
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

51 Longitudinal Acceptance
-500V Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

52 Longitudinal Acceptance
MENTION Negative field lines Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

53 Longitudinal Acceptance
-500V Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

54 Longitudinal Acceptance
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 26

55 Longitudinal Acceptance
NEXT Electronics Laser-based Beam Diagnostics for the RAL Front End Test Stand • 27

56 Readout Electronics Microprocessor controlled integrate and hold ADC with serial output to PC LabVIEW-based DAQ In the process of testing and fine-tuning production version Laser-based Beam Diagnostics for the RAL Front End Test Stand • 28

57 Readout Electronics Signal ~ pC, noise < fC NEXT Reconstruction
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 29

58 Reconstruction Currently envisaged that the profiles will be reconstructed using the Algebraic Reconstruction Technique (ART) algorithm Maximum entropy (MENT) also under consideration MENTION 5 Projections, 2 mm laser beam, Overlapping (50%?) Original Profile Reconstructed Profile Laser-based Beam Diagnostics for the RAL Front End Test Stand • 30

59 Conclusion A novel laser-based beam diagnostic that is able to measure the full profile of the FETS H− beam has been designed and constructed It is currently being installed at RAL And should be ready to make measurements on the first beam in a few weeks time Laser-based Beam Diagnostics for the RAL Front End Test Stand • 31

60 Spare Slides Laser-based Beam Diagnostics for the RAL Front End Test Stand • 32

61 ISIS Upgrades Diamond ISIS (0.24 MW) 3 GeV RCS 400-800 MeV Linac
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 33

62 For scale: CERN Laser-based Beam Diagnostics for the RAL Front End Test Stand • 34

63 For scale: CERN Laser-based Beam Diagnostics for the RAL Front End Test Stand • 34

64 For scale: CERN Laser-based Beam Diagnostics for the RAL Front End Test Stand • 34

65 For scale: CERN Laser-based Beam Diagnostics for the RAL Front End Test Stand • 34

66 H− Injection H− from Linac Stripping foil Circulating protons
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 35

67 FETS Ion Source 35kV 17kV Platform Ground Platform DC Power Supply
53.7mm 35kV 17kV Platform Ground Platform DC Power Supply Pulsed Extract Power Supply Post Extraction Acceleration Gap Laboratory Ground Extraction Electrode, Coldbox and Analysing Magnet all Pulsed 35keV H- Beam + - 18kV Mounting Flange 10mm Mica Copper Spacer Ceramic H- Ion Beam Extract Electrode Cathode Anode Penning Pole Pieces Discharge Region Aperture Plate Source Body Laser-based Beam Diagnostics for the RAL Front End Test Stand • 36

68 FETS LEBT Matches beam from the ion source to the RFQ
3 solenoid construction Solenoids and their power supplies complete Beam pipe design complete D S Laser-based Beam Diagnostics for the RAL Front End Test Stand • 37

69 Solenoid Focussing Second order focussing
Field gradient starts rotation of particles about axis This rotation then produces a focussing force towards the axis F, v, B Laser-based Beam Diagnostics for the RAL Front End Test Stand • 38

70 FETS RFQ Cold model complete Mechanical design study starting
RF tests underway to verify simulation mostly complete Mechanical design study starting Integrated with simulation work Lots to consider How to manufacture Cooling Laser-based Beam Diagnostics for the RAL Front End Test Stand • 39

71 Simon Jolly, Imperial College
RFQ Focussing RF field causes positive / negative charges on pairs of vanes. Since field varies with time, alternate focussing / defocussing mimics a FODO lattice. RFQ E-field Standard Quad RFQ vane tips Simon Jolly, Imperial College

72 RFQ Acceleration/Bunching
RFQ vane tips modulated longitudinally. Vane tip modulations produce longitudinal field: acceleration and bunching. Alternate modulation gives acceleration Single vane  = distance moved by particle in one oscillation + - Simon Jolly, Imperial College

73 FETS MEBT/Chopper (I) Matching between RFQ and DTL
Houses beam chopper to remove some bunches of the beam Laser-based Beam Diagnostics for the RAL Front End Test Stand • 42

74 FETS MEBT/Chopper (II)
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 43

75 Laser-based e± diagnostics
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 44

76 Laser Characterisation
Need a compromise between Having as high a resolution as possible Lots of bins in histogram But not having an over-focussed beam That would distort the measurement Laser-based Beam Diagnostics for the RAL Front End Test Stand • 45

77 H- profile comparison Initial particle distribution
H- distribution just past magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 46

78 H- phase space comparison
Initial particle distribution H- distribution just past magnet Laser-based Beam Diagnostics for the RAL Front End Test Stand • 47

79 H- phase space comparison
Laser-based Beam Diagnostics for the RAL Front End Test Stand • 48

80 Residual gas interactions
Assuming partial pressures of H2: 5x10-3 Pa N2: 5x10-5 Pa we loose ~2% of the beam per metre (or ~1.8x1013 ions per metre) So we need to minimise the fraction of these collected to minimise the background Laser-based Beam Diagnostics for the RAL Front End Test Stand • 49

81 Stray fields The ion source dipole field leaks into the diagnostic vessel Scott Lawrie (RAL) has designed shielding for this Deflections (with no E-field) Average deflection: 3.88 mm (with B-field) Average deflection: mm (no B-field) Deflections (with E-field) Average deflection: 2.44 mm (with B-field) Average deflection: mm (no B-field) Shielding sufficient With and w/out shielding? Laser-based Beam Diagnostics for the RAL Front End Test Stand • 50

82 ART Laser-based Beam Diagnostics for the RAL Front End Test Stand • 51

83 ART Laser-based Beam Diagnostics for the RAL Front End Test Stand • 52

84 ART Laser-based Beam Diagnostics for the RAL Front End Test Stand • 53

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