1. Low Alpha Operation at Diamond
Ian Martin
R. Bartolini , G. Cinque, M. Frogley, A. Morgun, G. Rehm, C. Thomas, R. Walker
XX European Synchrotron Light Source Workshop
Helmholtz Zentrum Berlin
20th November 2012

2. Talk Outline Low Alpha Lattice Instability Threshold Studies
Optics / Main parameters
Instability Threshold Studies
Mm-wave port, Schottky Barrier Diodes
Measured spectrograms / bursting thresholds / comparison with theory
Differences for positive / negative alpha operation
Differences for single bunch / multi-bunch operation
Low Alpha for Users
Modes of operation / how we operate
Machine performance / Beamline data
Conclusions
Low Alpha Lattice
Optics / Main parameters
Instability Threshold Studies
Mm-wave port, Schottky Barrier Diodes
Measured spectrograms / bursting thresholds / comparison with theory
Differences for positive / negative alpha operation
Differences for single bunch / multi-bunch operation
Low Alpha for Users
Modes of operation / how we operate
Machine performance / Beamline data
Conclusions
Ian Martin
ESLS XX, HZB, 20th Nov 2012

3. Lattice
user
low alpha
Ian Martin
ESLS XX, HZB, 20th Nov 2012

4. Lattice Parameter Standard User Lattice Low Alpha Lattice Emittance
2.7nm.rad
4.4nm.rad α1
1.7×10-4
-1×10-5
α2 (with/without sext.)
1.7×10-3 / 5.1×10-3
-2×10-5 / 0.005
α3 (with/without sext.)
-1.4×10-4 / 0.051
0.004 / 0.008
Tune point (Qx / Qy) /
/ 8.284
Natural chromaticity (ξx0 / ξy0)
-79 / -35
-66 / -43
σx / σy at IDs (0.2% coupling)
124μm / 2.9μm
94μm / 7.0μm
Energy spread
9.62×10-4
Damping times (hor. / long.)
11.2ms / 5.6ms
Natural bunch length (3MV)
10.0ps
2.4ps
Synchrotron frequency (3MV)
2608Hz
629Hz
Ian Martin
ESLS XX, HZB, 20th Nov 2012

5. Talk Outline Low Alpha Lattice Instability Threshold Studies
Optics / Main parameters
Instability Threshold Studies
Mm-wave port, Schottky Barrier Diodes
Measured spectrograms / bursting thresholds / comparison with theory
Differences for positive / negative alpha operation
Differences for single bunch / multi-bunch operation
Low Alpha for Users
Modes of operation / how we operate
Machine performance / Beamline data
Conclusions
Ian Martin
ESLS XX, HZB, 20th Nov 2012

6. Schottky Barrier Diodes
60-90GHz SBD
60-90 GHz
GHz
Sensitivity
28 V/W
1500 V/W
Response Time
<250 ps
~1 μs
Measurement Bandwidth
>4 GHz
~1 MHz
Pre-amp input impedance
50 Ω
100 kΩ
Pre-amp gain
60 dB
40 dB
GHz SBD
Ian Martin
ESLS XX, HZB, 20th Nov 2012

7. mm-wave beam port Installed during Dec 2011 shutdown
Increased power measured by SBD by factor ~3-4
Ian Martin
ESLS XX, HZB, 20th Nov 2012

8. Positive Alpha (4 Bunches)
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 81.1µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 97.2µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 8.5µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 63.0µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 21.9µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 45.0µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 30.8µA
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 37.7µA
Instability threshold
Ian Martin
ESLS XX, HZB, 20th Nov 2012

9. Instability Thresholds
Free-space CSR theory:
α1 > 0
Stupakov, Heifets, PRST-AB 5, (2002)
Byrd et al., PRL 89, (2002)
Ian Martin
ESLS XX, HZB, 20th Nov 2012

10. Instability Thresholds
Shielded CSR theory:
α1 > 0
From VFP simulations:
From free-space CSR theory:
Bane, Cai, Stupakov, PRST-AB 13, (2010)
Wuestefeld et al., IPAC 2010, p (2010)
Cai, IPAC 2011, p. 3774, (2011)
Ries et al., IPAC 2012, p (2012)
Ian Martin
ESLS XX, HZB, 20th Nov 2012

11. Negative Alpha (1 Bunch)
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 8.3µA
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 60.7µA
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 49.3µA
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 55.5µA
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 40.8µA
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 18.4µA
α1 = -1×10-5
VRF = 3.4MV
fs0 = 675Hz
Ibunch = 33.0µA
Bursting threshold
Instability threshold
Ian Martin
ESLS XX, HZB, 20th Nov 2012

12. Instability Thresholds
Instability threshold data
Free-space CSR theory:
α1 < 0
Stupakov, Heifets, PRST-AB 5, (2002)
Byrd et al., PRL 89, (2002)
Ian Martin
ESLS XX, HZB, 20th Nov 2012

13. Instability Thresholds
Bursting threshold data
Free-space CSR theory:
α1 < 0
Stupakov, Heifets, PRST-AB 5, (2002)
Byrd et al., PRL 89, (2002)
Ian Martin
ESLS XX, HZB, 20th Nov 2012

14. Comparison Single/Multibunch
α1 = -4.5x10-6
VRF = 3.4MV
fs = 450Hz
1 bunch
α1 = -4.5x10-6
VRF = 3.4MV
fs = 450Hz
400 bunches
Ian Martin
ESLS XX, HZB, 20th Nov 2012

15. Comparison Single/Multibunch
α1 = -4.5x10-6
VRF = 3.4MV
fs = 450Hz
1 bunch
α1 = -4.5x10-6
VRF = 3.4MV
fs = 450Hz
400 bunches
Ian Martin
ESLS XX, HZB, 20th Nov 2012

16. Talk Outline Low Alpha Lattice Instability Threshold Studies
Optics / Main parameters
Instability Threshold Studies
Mm-wave port, Schottky Barrier Diodes
Measured spectrograms / bursting thresholds / comparison with theory
Differences for positive / negative alpha operation
Differences for single bunch / multi-bunch operation
Low Alpha for Users
Modes of operation / how we operate
Machine performance / Beamline data
Conclusions
Ian Martin
ESLS XX, HZB, 20th Nov 2012

17. User Requirements NANOSCIENCE (I06) for short pulses
2 helical undulators
Use single bunch for time-resolved science
Preference for higher bunch charge over shortest absolute pulse duration (no benefit for reducing alpha)
Request stable beam (higher alpha for transverse stability and below bursting threshold)
MIRIAM (B22) for THz emission
Requirements depends on particular users and region of spectrum required
Can make use of beam in short pulse mode, but some experiments require CSR emission up to 100cm-1 => need to operate above bursting threshold
Ian Martin
ESLS XX, HZB, 20th Nov 2012

18. Lattice Parameters Short Pulse Mode THz Mode α1 -1×10-5 -4.5×10-6
Number of bunches
200
Bunch current
50 µA (93 pC)
Emittance coupling ratio
0.3% 1%
Lifetime
~20h
Injection efficiency (IDs open)
30-40%
15-20%
VRF
3.4MV
Micro-bunching instability threshold (SB)
~30-35 µA
~15 µA
Bursting threshold (SB)
~55-60 µA
~25-30 µA
Ian Martin
ESLS XX, HZB, 20th Nov 2012

19. Why negative alpha?
Negative alpha operation benefits both short pulse and THz users:
Bunch lengthening with current reduced
‘Sharper’ longitudinal profile
Measured instability thresholds similar
α1 = -1x10-5
VRF = 1.5MV
Ibunch = 25µA
α1 = +1x10-5
VRF = 1.5MV
Ibunch = 25µA
α1 = +1x10-5 / 1.5MV
α1 = -1x10-5 / 1.5MV
Ian Martin
ESLS XX, HZB, 20th Nov 2012

20. Bunch Length Target bunch current same for both modes Ian Martin
ESLS XX, HZB, 20th Nov 2012

21. Short Pulse Mode 19/07/2012 20/07/2012 Requested beam fill Ian Martin
ESLS XX, HZB, 20th Nov 2012

22. MIRIAM (B22) Spectrum Courtesy G. Cinque 03/10/2012 04/10/2012
05/10/2012
Courtesy G. Cinque
Ian Martin
ESLS XX, HZB, 20th Nov 2012

23. THz Mode 03/10/2012 04/10/2012 05/10/2012 Beam trip
Data acquisition paused
Mirror adjusted
Ian Martin
ESLS XX, HZB, 20th Nov 2012

24. Talk Outline Low Alpha Lattices Instability Threshold Studies
Optics / Main parameters
Instability Threshold Studies
Mm-wave port, Schottky Barrier Diodes
Measured spectrograms / bursting thresholds / comparison with theory
Differences for positive / negative alpha operation
Differences for single bunch / multi-bunch operation
Low Alpha for Users
Modes of operation / how we operate
Machine performance / Beamline data
Conclusions
Ian Martin
ESLS XX, HZB, 20th Nov 2012

25. Conclusions User operations: Main issues now well understood
Two lattices tailored to suit needs of individual beamlines
Reliable, ‘stable’ operation demonstrated for last couple of years
Top-up and FOFB big help in delivering this
Physics studies:
Strikingly different behaviour for positive / negative alpha (more investigations needed)
Earlier onset of instabilities in multi-bunch; bunches do not need to be adjacent in order to have measurable influence on neighbours
Still much to do:
Need better understanding of how different types of wakefield influence bunch
Develop an effective model that reproduces measured behaviour
Ian Martin
ESLS XX, HZB, 20th Nov 2012

26. Ian Martin
ESLS XX, HZB, 20th Nov 2012

27. No instabilities visible on either detector at higher frequencies
60-90GHz detector
GHz detector
No instabilities visible on either detector at higher frequencies
(VRF = 3.4MV, α1 = -1×10-5)
Ian Martin
ESLS XX, HZB, 20th Nov 2012

28. α1=-0.3x10-5 / VRF=1.5MV
α1=-0.3x10-5 / VRF=2.2MV
α1=-0.3x10-5 / VRF=3.4MV
α1=-0.3x10-5 / VRF=4.0MV

29. α1=-0.6x10-5 / VRF=1.5MV
α1=-0.6x10-5 / VRF=2.2MV
α1=-0.6x10-5 / VRF=3.4MV
α1=-0.6x10-5 / VRF=4.0MV

30. α1=-1.0x10-5 / VRF=1.5MV
α1=-1.0x10-5 / VRF=2.2MV
α1=-1.0x10-5 / VRF=3.4MV
α1=-1.0x10-5 / VRF=4.0MV

31. α1=-1.4x10-5 / VRF=1.5MV
α1=-1.4x10-5 / VRF=2.2MV
α1=-1.4x10-5 / VRF=3.4MV
α1=-1.4x10-5 / VRF=4.0MV

32. α1= 0.3x10-5 / VRF=1.5MV
α1= 0.3x10-5 / VRF=2.2MV
α1= 0.3x10-5 / VRF=3.4MV
α1= 0.3x10-5 / VRF=4.0MV

33. α1= 0.6x10-5 / VRF=1.5MV
α1= 0.6x10-5 / VRF=2.2MV
α1= 0.6x10-5 / VRF=3.4MV
α1= 0.6x10-5 / VRF=4.0MV

34. α1= 1.0x10-5 / VRF=1.5MV
α1= 1.0x10-5 / VRF=2.2MV
α1= 1.0x10-5 / VRF=3.4MV
α1= 1.0x10-5 / VRF=4.0MV

35. α1= 1.4x10-5 / VRF=1.5MV
α1= 1.4x10-5 / VRF=2.2MV
α1= 1.4x10-5 / VRF=3.4MV
α1= 1.4x10-5 / VRF=4.0MV

36. Talk Outline α1 = +1×10-5 VRF = 3.4MV fs0 = 675Hz Gap = 0 α1 = +1×10-5
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Gap = 0
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Gap = 1
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Gap = 9
α1 = +1×10-5
VRF = 3.4MV
fs0 = 675Hz
Gap = 4
Ian Martin
ESLS XX, HZB, 20th Nov 2012

37. (VRF = 3.4MV, α1 = -1×10-5) quadratic linear Ian Martin
ESLS XX, HZB, 20th Nov 2012