Present Lattice Structure of the SPring-8 SR 4 [ 9 (Normal Cell, DB) + (Matching Cell) + (Long Straight) + (Matching Cell) ] Matching LS MatchingNormal C = 1436 m E = 8 GeV = 3.4 nmrad ( eff = 3.7 nmrad ) 3
LER2011 Lattice Team K. Soutome, Y. Shimosaki, T. Nakamura, M.
Takao, T. Tanaka K. Soutome (JASRI / SPring-8) on behalf of
SPring-8 Upgrade Working Group SPring-8 Upgrade: Lattice Design of
a Very Low-Emittance Storage Ring Talk based on the work by Y.
Shimosaki, IPAC2011, "Lattice Design of a Very Low-emittance
Storage Ring for SPring-8-II" 1 Ultimate Target of Machine
Upgrading "Diffraction Limited" Light Source in Both H. and V.
Directions for ~ 10keV Photons ~ 10pmrad E = 6 GeV I = 100 mA =
0.02 = 0.12% x = 1 m y = 1 m 10 keV Photon by Hybrid Undulator by
T.Watanabe SPECTRA 2 Present Lattice Structure of the SPring-8 SR 4
[ 9 (Normal Cell, DB) + (Matching Cell) + (Long Straight) +
(Matching Cell) ] Matching LS MatchingNormal C = 1436 m E = 8 GeV =
3.4 nmrad eff = 3.7 nmrad 3 Way of Upgrading Convert present DB
cell to Multi-Bend cell. Reuse the present machine tunnel. Keep the
number and position of present ID-BLs. Lower the energy: 8GeV 6GeV
(or lower) Hard X-ray is covered by undulator upgrading (short
period). Reduce the emittance with damping wigglers. Control the
coupling (if necessary). 2B: 1.9nmrad (Non-Achomat, 6GeV) 3B:
0.43nmrad 4B: 0.16 nmrad 6B: 0.07 nmrad (Achomat) : Strong Q Large
Nat. Chrom. Small Dispersion Strong SX Small DA "Chromaticity Wall"
(J.Bengtsson, EPAC08) We set 6B lattice as a candidate of a new
ring. 4 Multi-Bend Lattice 3 Theoretical Minimum Emittance (TME) M
Half-Length B at Both Ends of Unit Cell (Achromat) D.Einfeld and
M.Plesko, NIMA335 (1993) 402 5 Multi-Bend Lattice 2B ( eff =
2.09nmrad) 3B ( eff = 0.54nmrad) 4B ( eff = 0.19nmrad) 6B ( =
0.07nmrad) Multi-Bend Lattice 6B Lattice LBLB LBLB LBLB LBLB L B /2
x 1m y 1m x = 0 matchin g unitmatchin g unit 7 Multi-Bend Lattice
Inj. Point Normalized by 1/2 8 Multi-Bend Lattice (N B -1) -3 NB: L
B /2 at both ends (N B -1) 8B 10B 12B 9 Multi-Bend Lattice Number
of B Quad. Tune Chrom.(abs) Dispersion Chromaticity Cor. Sextupoles
Dynamic Apt. 10 too small DA for M > 6 6B Lattice Design
(typical) 11 2B (Double-Bend) Dispersion Leaked 6B (Sextuple-Bend)
Achromat Unit Cell Length m Ring Circumference m Beam Energy8 GeV6
GeV Emittance3.4 nmrad (3.7 nmrad)0.068 nmrad Energy Spread0.109
%0.096 % Betatron Tune (H/V) / / Natural Chromaticity (H/V)-88 / /
-191 Momentum Compaction1.68e-41.55e-5 Beta at Normal Straight22.6
m / 5.6 m1.0 m / 1.4 m Bending Field0.68 T0.70 T No. of Quadrupoles
/ Cell1026 (9 Family) Max. Quad. Str. B'L/(B ) 0.40 m m -1 (B' = 79
T/m) No. of Sextupoles / Cell723 (12 Family) Max. Sext. Str.
B''L/(B ) 6.2 m m -2 (B''=13000 T/m 2 ) Radiation Loss9 MeV/turn4
MeV/turn 12 v Bending Field Dependence of Chromaticity Use 6B
lattice with 0.7 T / 0.9 T / 1.4 T bending field, vary QF and QD
and find optics having the emittance of less than 90pmrad. 13 Nat.
Chrom. & Rad. Power & Emit. Reduction by DW 0.7 T SF/2 SF
SD Interleaved SX Configuration within a Cell Basic Idea:
Cancellation of SX Kicks within a Cell (Hor.) small but non-zero DA
14 - I transformation SF/2 SF SD Interleaved SX Configuration
within a Cell Actual Consraints we put in SX Optimization 15 - I
transformation To increase SX degree of freedom, we relaxed the
constraints and added harmonic SXs outside the arc. 12-family
(mirror sym.) close but not the same strength Betatron phase
advance x ~ 25 x ~ Interleaved SX Configuration between Cells Cell
1 Cell 3 Cell 5 Cell 1 Cell 3 y ~ 3 Cell 5 Horizontal Vertical - I
transformation cf.) "sextupole symmetrization" in SLS 16 We found
the vertical constraint is effective. DA becomes double in vertical
direction. Linear Optics as low natural-chromaticity as possible
(so that SX becomes weak) Tune Selection (1) avoidance of strong
resonances (2) phase adjustment for interleaved sextupole
configuration Design of Nonlinear Optics harmonic method with
interleaved SX for correcting (1) linear chromaticity (2) nonlinear
resonances independent of p/p (on- and off-mom.) (3) nonlinear
resonances by Q and SX for off-mom. (4) higher order resonances for
on-mom. (5) amplitude-depence of tune Iteration (tune survey, etc)
Strategy of Lattice Design 17 + (On-momentum) Higher Order Resonant
Potentials by Sx Resonant Potential Induced by SX without p/p (Qx,
Qy): Tune (Off-momentum) Resonant Potential by Q (Off-momentum)
Resonant Potential by Sx Cancel Set to ~ 0 Suppress Isolated
Resonance Hamiltonian Design of Nonlinear Optics Sextupole
Optimization (latest) Amplitude- and Energy-Dependence of Tune 19
Sextupole Optimization (latest) 20 Sextupole Optimization (latest)
21 Frequency Map ( = 0%) Dynamic Aperture w/o Inj. Point (LSS) x =
24.2 m, y = 7.8 m x = 40 m DA Boundary x: integer resonance y:
sextupole resonance Sextupole Optimization (latest) 22 DA w/ SX
Alignment Error ( = 10 m, cutoff 2 Sextupole Optimization (latest)
Momentum Acceptance 23 Damping by Insertion Devices Residual
dispersion must be suppressed: x < 1mm Planar ID ( U = 14.4mm, L
= 3m) 28 the same number as normal straights At user-time: 67pmrad
around 30 pmrad 24 Damping Wigglers At user-time 67pmrad around
30pmrad DWs are used to realize an extremely small emittance less
than 20pmrad. They can also be used to keep the emittance at some
value during user- time (compensation of ID gap change). Add DWs (
DW = 50mm, L DW = 4m) at LSSs. 25 Intrabeam Scattering &
Touschek Lifetime Emittance and Energy Spread Ref.) K.Bane, PRST-AB
5 (2002) K.Kubo, PRST-AB 8 (2005) Touschek Lifetime cf.) 1nC/bunch
0.2mA/bunch Bunch Length (rms): 7.7 10 ps Control of bunch length
is under consideration. 26 w/o ID Brilliance About 10 3 times
higher brilliance than that of the present storage ring (0.5 ~ 100
keV). by T.Tanaka New (6GeV, 300mA) Present (8GeV, 100mA) ID
Parameters (tentative) 28 30m-LSS for Beam Injection One example of
LSS Optics (to be optimized) No Sextupoles (Linear) Low Natural
Chromaticity Betatron-Phase Matched High for Beam Injection also
for Damping Wigglers / RF x, y 29 Injector A high-quality injection
beam is needed. At SPring-8 we have XFEL Linac, which will be used
as a full-energy injector to the storage ring. Energy: 8 GeV (max.)
Emittance: 40 pm.rad Energy Spread: 0.01 % Bunch Length: 30 fs
(rms) Electron Charge: 300 pC 1 nC XFEL(SACLA) SR Booster Design
Parameters (typical) 30 Summary SPring-8 upgrade plan is under
discussion. 6B lattice is a current tagret : 70 pmrad (natural, at
6GeV) < 20 pmrad (w/ damping) Brilliance > Studies are
ongoing including further optimization of lattice. DAY-3 K.Fukami,
"Strong Magnets for Ultimate Storage Rings" T.Nakamura, "A Fast
Kicker System for Beam Injection" 31 IPAC2011 Papers T. Watanabe,
et al. Current Status of SPring-8 Upgrade Plan Y. Shimosaki, et al.
Lattice Design of a Very Low-emittance Storage Ring for SPring-8-II
T. Nakamura Bucket-by-bucket On/Off-axis Injection with Variable
Field Fast Kicker M. Masaki, et al. A Proposal of Short X-ray Pulse
Generation from Compressed Bunches by mm-wave iFEL in the SPring-8
Upgrade Plan K. Fukami, et al. Beam-based Alignment for Injection
Bump Magnets of the Storage Ring using Remote Tilt-control System
32
