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Injector Requirements Ccile Limborg, SLAC November 3, 2003

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Title: Injector Requirements Ccile Limborg, SLAC November 3, 2003

1
Injector RequirementsCécile Limborg,
SLACNovember 3, 2003

Physics Performance Requirements
Operating range of parameters
Tolerances, Safety Factors
Updated tuning for matching section
Tuning with longer pulse
Sensitivity
LSC simulations
Conclusion
Documentation

2
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3
Objective

?projected lt 1.2 mm.mrad
?slice lt 1.0 mm.mrad for 80 slices out of 100
?slice (80) projected emittance for the core
80 slices
for 1nC, 10ps pulse at 135 MeV ,in the presence
of jitter errors at 120Hz

Gun E (MV/m) ? Balance ?th
Solenoid Position Length Field
Solenoid 2 Position Length Field
Linac0-1 Position E(MV/m)
Linac0-1 Position E(MV/m)
Laser Parameters Longitudinal (length, rise time,
flatness) Transverse(r, uniformity, pointing
spot) Energy ? charge
19 parameters to optimize
4
Simulations - Nominal tuning

1nC, 10ps, rlaser spot 1.2 mm
Thermal emittance of 0.72 mm.mrad (assumes 0.6
per mm radius)
Finite rise time of 0.7ps (from 10-90 level)

5
Sensitivity Studies Single parameter variation
Solenoid 1 ?0.3
Egun ?0.5
?gun ?2.5 ?
Balance 3 is ok
Linac Field 12 (EFinal 150 MeV )
Solenoid 2 20
6
Sensitivity Studies - Combination of Errors

Using extreme values of parameters deviations
meeting regulation specifications

26 possibilities 64 runs
7
Operating Range and Sensitivity

8
Tolerances Alignment and Laser Uniformity

() combined with uniformity of QE

9
First Linac Section Alignment

Effects of Wakefields
Position ?150 ?m maximum
Angular 120 ?rad
With alignment steering those requirements
are easily met (BPM resolution 10 ?m )

At end beamline
At end beamline
2 increase level
2 increase level
10
Requirements on Laser Pulse - Summary

? 120 ?m
? 240 ?m
? 480 ?m
11

Laser Quality Transverse Uniformity
High frequency modulations get diluted , low
frequency is the most damaging
Slope across Spot
Offset of center of gravity ? transverse
wakefield in linac
Criteria deterioration of slice emittance at
linac entrance by less than 5
or center of gravity off by less than
100 ?m at linac entrance
Result No more than /- 15 (/- 10 feasible
and will be the tolerance)

Laser Quality Transverse Uniformity
Checker board type low frequency is worst
case 1
Generates ellipticity but no centroid offset
Generates slice emittance growth
Result maximum / 15 modulation
(again 10 feasible and is the specification)

Example of high frequency structure

14
Laser Quality (ignoring LSC)

Longitudinal Flat top Flatness
Emittance deterioration
Result
For ?gt 240 ?m , Modulation lt 20
For 240 ?m lt ?, Modulation lt 30

Case of ?? 480?m Modulation 20
? 120 ?m
? 240 ?m
? 480 ?m
20 peak-to-peak
15
Updated tuning - 135 MeV

Final energy 135 MeV
Linac-02 at 24 MV/m instead of 28.7 MV/m
to prevent dark current at end L0-2 (noise on
OTR screens)
No emittance growth at 135 MeV
Limit checked to be 120 MeV for emittance growth

16
Updated tuning - add quadrupoles in L01-to-L02

Modification of beamline
Added two quadrupoles between L0-1 and L0-2
Justification
Beam sizes too large at exit L0-2
PARMELA simulations had been misleading
Showing artificially small beam sizes
(problem of sampling in linac section,
introduced by too large time steps)
A Solenoid cannot provide the necessary focusing
Provides even more tuning flexibility

17
Updated tuning - add quadrupoles in L01-to-L02

Add 2 quadrupoles in the 1m drift between L0-1
and L0-2
PARMELA With Space Charge
Matching Section
18
Tuning with longer laser pulse

Objective
Decrease emittances (slice, 80) to have larger
margin for emittance growth
as more compression possible from BC1 (thanks to
laser heater)
Explanation
Smaller thermal emittance by reducing spot size
radius
Issues
Strong Non-linearities in longitudinal phase
space?
Sensitivity increased (injection phase, solenoid
fields , transverse wakes)?
Difficult to compress ?
Changes laser requirements ?
First tunings (15 ps, 17.5 ps, 20 ps)
Very good slice emittance
Strong compression in gun (helps on 1.)
More sensitive to injection phase (still well
within tolerances)
Matching not as good, but compression does not
seem yet to present any problem
Still To be checked
Transverse wakefields

19
Tuning with longer laser pulse
20
Sensitivity Comparison case of 17.5 ps with
nominal 10 ps tuning
Solenoid Field Same sensitivity
Gun field Long pulse tuning less sensitive
Injection Phase Long pulse tuning more sensitive
21
LSC (Longitudinal Space Charge ) Instability

Plasma oscillation in a coasting beam

Current Density
Energy

The self-consistent solution is the space charge
oscillation

22
LSC (Longitudinal Space Charge ) Instability

Comparison with theory in drifts
Good match for energy
Simulations in gun

23
LSC Simulations in gun
20 ? 14 rms 10 ? 7 rms 5 ? 3.5 rms

Limitations of PARMELA
Difficulties to study LCLS pulse
Study of ? 50 ?m , dz 5 ?m
?z 5 mm
Nz x Nr 1000 x 20
200k particles
Per longitudinal bin 200 particles , 1/?200 7
? For initial modulation of less than 7
modulation of current density at gun exit is in
noise
Case studied
? 50 ?m, 100 ?m, 250 ?m, 500 ?m, 1000 ?m
For /-10 and /- 20 initial modulation
amplitude

Noise Level 4 From uniform distribution
24
LSC Simulations in gun

Other cases under study for a shorter pulse than
the LCLS pulse for 5 ptp
Modifications to ASTRA to improve statistics
Weight on particle charge
Adaptative meshing (for higher density of
particles)
Can study modulation on core of bunch without
introducing edge effects
Objective give definitive specifications for
flatness of flat top of laser pulse ( assuming
laser heater will be on)

gun
drift
25
CONCLUSIONS

Tolerances on components well understood
Wakefield studies under way
Very promising preliminary results new tuning (
Long pulse)
More sensitivity studies
Start-to-End simulations
LSC
Theory and simulations at advanced stage
Understanding laser pulse requirements in the
presence of laser heater

26
DOCUMENTATION

Nominal tuning
1 Sensitivity studies for the LCLS
PhotoInjector Beamline , FEL03 conference
2 New tuning at 135 MeV , LCLS-INJ Note
New tuning
3 Tuning with longer pulse , still to be
written
LSC
4 LSC Instability S2E simulation Workshop ,
August 03, Berlin

27
DOCUMENTATION

Diagnostics
6 Gun Spectrometer C.Limborg , March 03
updated October
7 Gun Spectrometer, Revision 1, C.Limborg,
LCLS-InJTech Note
8 Gun Spectrometer, Revision 2, C.Limborg,
LCLS-InJTech Note
9 Straight-Ahead Spectrometer, C.Limborg,
April 03, LCLS-InJTech Note
10 Straight-Ahead Spectrometer, Revsion 1,
C.Limborg, Oct03, LCLS-InJTech Note

BACK- UP
SLIDES

29
Tuning with gun unbalanced by -20 in ½ cell

At gun exit
At Linac 0-2 exit

Field in 1/2 cell 80 of field in full cell
?projected 0.91 mm.mrad
Small degradation compared balanced case
?projected 0.80 mm.mrad
(1nC,10ps,0.5ps rise time,?th 0.3 mm.mrad)
Only Solenoid field change by 3.5
Bfield 2.61 kG instead of 2.71 kG
Changing ?gun does not improve
At entrance booster ?E 500 keV

At entrance Linac 0-1
30
Physics Performance Requirements

Charge
7 ok , objective 5
Laser Spot Size
1 very easy to maintain

31
Physics Performance Requirements

Laser Quality
Longitudinal Flat Top Flatness
Source of CSR in BC2 if modulation in range 100?m
lt ? lt200 ?m
Result favorable situation since good dilution
for short wavelengths (? lt 240 ?m )

32
Physics Performance Requirements