Part III Technology of Insertion Devices...BWLF [T] [mm] [m] [kN] Undulator 0.8 40 1.6 8.1 Wiggler...
Transcript of Part III Technology of Insertion Devices...BWLF [T] [mm] [m] [kN] Undulator 0.8 40 1.6 8.1 Wiggler...
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Part III Technology of Insertion Devices
Pascal ELLEAUMEEuropean Synchrotron Radiation Facility, Grenoble
III, 1/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Technology of Undulators and Wigglers
III, 2/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
• The main issue in the magnetic design of a planar undulator or wiggler is to produce a sinusoidal field with a high peak field B and the shortest period λ0within a given aperture (gap).
• Three type of technologies can be used :– Permanent magnets ( NdFeB , Sm2Co17 )– Room temperature electromagnets ( iron and coils )– Superconducting electromagnets (superconducting coils with or without iron)
Gap
Period
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Current Equivalent of a Magnetised Material
M ⇔
0
[ ]Air coil with Surface Current Density[A/m] rB Tµ
≅
III, 3/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Periodic array of magnets
0λ
⇔
0
0
2
0
2 [ ]Surface Current Density[A/m]
4 [ ]or Current Density[A/m ]
r
r
B T
B T
µ
µ λ
≅
≅
r 02
Example: B =1 T , λ =20mm
Equiv. Current Density=160A/mm !!
⇒
III, 4/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Permanent Magnet UndulatorHybrid Pure Permanent Magnet
Magnet (NdFeB, Sm2Co17,...)
Pole(Steel)
III, 5/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Magnetic Field of a Pure Permanent Magnet Undulator(Halbach Formula)
gaps
z
O
λ0
h
Assume relative permeability of magnet =1with remanent field Br, then the exact field computation gives :
0 0 0
sin( )4 2 exp( )(1 exp(2 )) cos(2 )
4
n r
n gap h sB B n n nn λ λ λ
π
= − π − π ππ
III, 6/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
0
0
0
if 1 exp(2 ) 12
exp( )
1 dominates
n r n
hh n
gapB B b n
n
λλ
λ
> ⇒ − π
⇒ = − π
⇒ =
∼
0 0
( ) 1.8 exp( )cos(2 )z rgap sB s B πλ λ
≈ −π
b1 0.90b3 0.30b5 -0.18b7 -0.13
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Field from Pure Permanent Magnet vs Hybrid
Hybrid
0.1
2
3
4
5
6789
1
2
Mag
netic
Fie
ld [T
]
1.00.80.60.40.2Gap / λ0
Magnet Volume = 2 N λ03
Lx Magnet = 2 λ0 First Harmonic Peak Field
Hybrid (Vanadium Permendur)
Pure Permanent Magnet
Pure Perm.Magnet
III, 7/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Numerical Computation of Magnetic Field
• No Iron (perm. magnet & coil )– Integration of Biot and Savart Law
– Simple Numerical Methods based on the current sheet or surface charge model. The total field is the linear sum of the field produced by each block. Particularly simple and efficient for parallellepipedic shapes
• With Iron ( perm. magnet & coil & iron) : Best solved with numerical methods
– Finite Element Method• Used dominantly for Dipole/Quadrupole/Sextupole … Magnets • 2D : POISSON (Public Domain)
– from http://laacg1.lanl.gov/laacg/services/possup.html• 3D : Commercial Codes (TOSCA, FLUX3D, ANSYS,…)
– Volume Integral Method : Radia• Particularly adapted to undulators and Wigglers • Compute field and field integral in 3D• Public Domain http://www.esrf.fr/machine/groups/insertion_devices/Codes/software.html
0 2
ˆdl uB Ir
µ ×= ∫
III, 8/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Design Process
User Requirements :Photon Energy Range
Linear/Circular PolarizationDivergence, Power Pre-Design :
Choice of TechnologyWiggler/Undulator
Period, Field,Length
Machine Constraints :Minimum Gap
Electron Energy
Radiation Computation :With Ideal Field
Photon Energy RangeBrilliance, Flux Detailed Design :
Central PeriodEnd designBeamline Design :
…
Construction
Field Measurement and Shimming
Install in the Ring
Measurements of Radiation
Radiation ComputationWith Real Field
Measure effect On the e-beam
III, 9/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Magnetic Forces
Force between upper and lower magnetic arrays :
0
2
4
ˆ
µWLBForce =
B W L F[T] [mm] [m] [kN]
Undulator 0.8 40 1.6 8.1Wiggler 1.5 120 1.6 85.9
FF F
FF
Force on each magnet can be large :⇒ rigid holding structures⇒ special assembly tools
III, 10/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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ESRF Undulators
Magnetic Force : 1-10 TonsGap Resolution : < 1 µmParallellism < 20 µm
III, 11/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Undulators are Fundamentally Small Gap Devices
• Like any accelerator magnet, the smaller the magnetic gap the less volume of magnetic material required to reach a specific field geometry.
• The lower the gap the higher the energy of the harmonics in the undulator emission.
20
2
0 0
00
(1 )2 2
0.0934 [ ] [ ]
1.8 exp( )
n
r
Kn
withK B T mm
gapB B
λλγ
λ
πλ
= +
=
−∼
III, 12/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Application : Build a pure permanent magnet undulator with NdFeB Magnets (Br = 1.2 T)
Undulator with K=1
Gap [mm]
B [T]
Period [mm]
Fundamental [keV]@ 6 GeV
ElectronEnergy [GeV]
Fund = 15.2 keV
15 15.210.38.2
226.07.3
28 8.2
5 0.7210 0.4915 0.38
III, 13/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Flexible Chambers
ESRF
NSLS
III, 14/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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In Vacuum Undulators
- Developed at NSLS, Spring-8 , ESRF- Required by many new light sources
(SLS,CLS,LBL,Diamond,Soleil,..)- Open the gap during injection if needed- Allow a minimum magnetic gap of 3 to 6 mm
III, 15/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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ESRF In-vacuum Undulator
III, 16/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Electro-Magnet Undulator
-Limited by the electrical powerrequirement and associated coolingof the coils :Current Densities < 10-15 A/mm2
-Only interesting for long periods
III, 17/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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SRC Electro-magnet Undulator (Wisconsin USA)
http://www.src.wisc.edu/research/highlights/undulator/default.html
III, 18/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Delta Superconducting Wiggler
- High field : up to 10 T => Shift the spectrum to higher energies- Sophisticated engineering & high cost
III, 19/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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SRS Superconducting Wiggler
III, 20/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Local Field Measuring Bench
Optimized for fast longitudinalfield scanning :- Optical & Laser Encoder- 3-axis Hall probe sensor- On-the-fly scanning 2000pts/m- Measuring length 2-10 m- Essential for phase shimming
III, 21/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Field Integral Measuring Bench
Either :-Rotating multiturn coil-Moving stretched wire
-Measure Horiz & Verticalsingle and double field integrals- Absolute accuracy < 10 Gcm- Essential for multipole shimming
III, 22/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Magnetic Field Errors of Permanent Magnet Insertion Devices :
• Originate from :– Non uniform magnetization of the magnet blocks (poles).– Dimensional and Positional errors of the poles and magnet blocks. – Interaction with environmental magnetic field
• Need to purchase highly uniformly magnetized blocs and – perform a systematic characterization – Perform a pairing of the blocks to cancel field integrals– but still insufficient .
• Type of Field Errors– Multipole Field Errors (Normal and skew dipole, quadrupole,
sextupole,…). – Phase errors which reduce the emission on the high harmonic numbers
III, 23/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Undulator Shimming
• Mechanical : Moving permanent magnet or iron pole vertically or horizontally
• Magnetic : Add thin iron piece at the surface of the blocks– More precise and local– Field reduction
III, 24/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Magnetic shims
Phase Shim
Phase Shim
III, 25/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Field Integral and Multipole Shimming
Horizontal DeflectionQuadrupoleSextupole …
Vertical DeflectionSkew QuadrupoleSkew sextupole …
Gap/2 [mm]
III, 26/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Phase Error and Phase Shimming
Each pulse interfere constructively If Tp =T for all p and for a wavelength sothat λ=2T/n where n is an integer (harmonic number). Real undulators have small field errors which result in fluctuations of Tp. These are also called phase errors.
TpTp+1 Tp+2
III, 27/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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2
2
( )
Assuming: identically independently distributed for every p with :
, ( )
Then , it is a consequence of the Fourier Transform that :
(0,0, )
ind
(0,0 )
e
,T
p
p p T
nn n Tn n ideal
x z x z
T
T T T T
d d ed dd d d d
σπ
σ
λ λλ λθ θ θ θλ λ
−
= − =
Φ Φ=
The effect is usually characterised by a rms phase errorpendently of t
expressed1in
he
degr
number of period
ees. [deg]80
N
=
1T
T
σσσ
On-axis angular flux, flux and brilliance are multiplied by 2( )Tn
Teσπ−
Phase error [deg] 6 1Harmonic #
1 0.99 1.005 0.76 0.999 0.41 0.98
13 0.16 0.95
III, 28/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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A Practical Example of Phase Shimming of an ESRF Undulator :(period 35 mm, N= 46 periods, Gap=11 mm)
Measured Vertical Field
- 0 . 6
- 0 . 4
- 0 . 2
0 . 0
0 . 2
0 . 4
0 . 6
2 .01 .51 .00 .50 . 0m
Calculated Trajectory @ 6 GeV Calculated on-axis single electron emission spectrum
-6
-5
-4
-3
-2
-1
0
1
2
3
4
µm
2.22.01.81.61.41.21.00.80.60.40.20.0m
9 deg. rms
1.7 deg. rms 1.0
0.8
0.6
0.4
0.2
0.0
x1018
403020100keV
III, 29/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.
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Remarks on Phase Errors
- Small phase errors may have a large impact on the undulator spectrum in particular on the high harmonic numbers. The associated magnetic field errors can be detected on the field plot where they appear as period and peak field fluctuations. Some of them (generating internal angles) may also be visible from the wandering of trajectory.
- Emittance and energy spread induce a broadening of the peak and may mask a part of the spectral flux lost due to phase errors. Nevertheless, in most cases, even with large emittance and energy spread, low phase error undulators perform much better on the high harmonics.
- They are important for long undulators or undulators intended to be used on a high harmonic number
- They are usually not important in undulators used on the fundamental of the spectrum such as in Free Electron Lasers
III, 30/30 , P. Elleaume, CAS, Brunnen July 2-9, 2003.