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P. Emma, N. Holtkamp, H.-D. Nuhn, SLAC C . Doose, J. Fuerst, Q. Hasse, Y. Ivanyushenkov, M . Kasa, G. Pile, E. Trakhtenberg, E. Gluskin, ANL D . Arbelaez, J. Corlett, S. Myers, S. Prestemon , R. Schlueter, LBNL.
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P. Emma, N. Holtkamp, H.-D. Nuhn, SLAC C. Doose, J. Fuerst, Q. Hasse, Y. Ivanyushenkov, M. Kasa, G. Pile, E. Trakhtenberg, E. Gluskin, ANL D. Arbelaez, J. Corlett, S. Myers, S. Prestemon, R. Schlueter, LBNL A Plan for the Development of Superconducting Undulator Prototypes for LCLS-II and Future FELS P. Emma, …for the SCU R&D collaboration: ANL, LBNL, SLAC August 28, 2014
Kicking the Can Down the Road (SCU’s)… • Proposed by E. Gluskin & N. Vinokurov in 1999 for LCLS-I“not ready for SCU” (15yrsago!) • Propose to re-design LCLS-II undulator and greatly improve performance (1 TW & 7 keV)? • SCU’s operating in ANKA (2005) & APS (2013) right now • Greatest un-tapped potential available for FEL performance
Superconducting Undulator Motivation Advantages of an SCU: • Higher magnetic fields allow superior FEL performance. • No permanent-magnetic material to be damaged by radiation longer life & smaller gaps. • Reduced (?) resistive wakefield with cold bore (preliminary). • Much lower vacuum pressure, which limits gas scattering. • Smaller footprint and simpler K-control than typical, massive adjustable-gap PMU. • Easily oriented for vertical polarization*. SCU’s need practical development… * Vertical polarization allows efficient x-ray transport in horizontal deflections
SCU’s Provide Much Higher Fields than PMUs SCU much higher field for given period and gap Nb3Sn NbTi LCLS-II SCU In-Vac. PMU PMU LCLS-II PMU: lu = 26 mm Bpk = 1.0 T gm= 7.3 mm 5-mm vac. gap for all (7.3-mm mag. gap) In-Vacsame vac. gap (5.3-mm mag. gap)
Und. Length vs Upper-limit Photon Energy (LCLS-II) 2-m segments & 0.7-m breaks In-Vac-5 In-Vac-5 NbTi-5 Nb3Sn-5 Lower-limit photon energy = 1.5 keV (at 4 GeV) in all cases Nb3Sn-5 In-Vac-5 NbTi-5 PMU-5 Self Seeded 4.8 keV Limit 145 m 145 m/1.5 In-Vac-5 NbTi-5 7.6 keV 6.5 keV NbTi-4 In-Vac-4 Nb3Sn-4 PMU-4 lu = 25.8, 24.4 mm, 22.9, 21.3 mm, 19.3, 18.4,mm, 17.7, 16.8 mm Kmin = 0.66, 0.64, 0.65, 0.65, 0.65, 0.64, 0.63, 0.63 Kmax= 2.4, 2.5, 2.6, 2.7, 2.9, 3.0, 3.1, 3.2 Bmax < 2.1 T Includes breaks & 20% length margin for SASE saturation “5” labels (PMU-5) have 5-mm vac. gap; “4” have 4-mm “In-Vac” has same vac. gap, but 2-mm smaller mag. gap
“TW-FEL” with SCU & Cu-Linac (LCLS-II) Step-wise tapered undulators (20%) 1.6 TW (4 keV) 4 GeV (1 MHz) 3-15 GeV (120 Hz) 1 MHz SXU SC-Linac Cu-Linac HXU Choose und. segment length (2 m) similar to gain length (1 m) to maximize peak power switch SCU 120 Hz Self-seeding monochromator C. Emma, C. Pellegrini, Z. Huang
Resistive-wall Wake of Cold-bore Undulator 4 GeV (Gaussian bunch) Rectangular chamber 4-mm chamber gap height 9mm rms bunch length L = 100 m, ~4K 2r 0.08% Resistive-wall wakefield due to anomalous skin effect at ~4 K Based on work by B. Podobedov, PRSTAB, 12, 044401 (2009), and new G. Stupakov, K. Bane model (preliminary)
SCU R&D Plan • ANL… • Build 2-m test cryostat (existing design) • Build & test 1.5-m long NbTi prototype und. (lu 21 mm) • LBNL… • Build & test 1.5-m long Nb3Sn prototype und. (lu 19 mm) • Develop meas. & tuning schemes (small tuning cryostat) • All Labs… • Develop field measurement and correction techniques • Demonstrate predicted field, field quality, end corrections, and cold-mass integration into cryostat • Develop conceptual design for full-length SCU in LCLS-II • Goal: By July 2015, deliver 2 fully functional, 1.5-m long, SCU prototypes meeting LCLS-II HXU spec’s
(Nb3Sn) Prototype Magnet - LBNL Nb3Sn to NbTi joints at end of undulator gm= 8 mm lu= 19 mm Wire Pocket (8×7) Nb3Sn Electron Beam Nb3Sn 0.6-mm diam. wire, 60-mm braid insulation Bpk= 1.86 T IEEE Trans. on App. Supercon., Vol. 17, No. 2, June 2007 , pp. 1243-1246. Load Lines Critical Current, Ic 8×5 On-Axis Field 8×7 Peak Conductor Field Design Point 8×9 6-period prototype (Nb3Sn) built at LBNL in 2006 - reached 97% of current (lu= 14.5 mm).
Undulator Assembly Components - LBNL Cooling plates are separate to allow Nb3Sn heat processing (~650 C)
SCU Tape Phase Correction Scheme - LBNL Single-turn correction coils placed on each side of vacuum chamber Needs demo May not be necessary? single turn correction coils current (< 100 A) heater switches S. Prestemon, D. Arbelaez, LBNL
Prototype Magnet - ANL (NbTi) Wire pocket (53 turns) lu= 21 mm gm= 8 mm NbTi e- 0.7-mm diam. Supercon NbTi SC wire Bpk= 1.66 T Lower risk, but less field Short test cores to verify tolerances and recent 1.1-m SCU1 now powered Load Lines Ic curve On-Axis Field 745 A @3.8 T Recent, very encouraging SCU1 results! (not shown) (1.66 T, 600 A, @80% Ic) Peak Cond. Field (3.35 T @80% Ic)
End-coil Winding Scheme - ANL End-Terminations and Field Correctors 0 ,51,100 Amp (Measurements) Precision cores & precision winding! Tolerance: 40 G-cm “SCU” being wound on bench 15/15 15/38 53 energized by main supply (600 A) winding pack front face Fully wound 1.1-m half-magnet energized by separate supply (70 A) shows 11 complete coil packages
ANL 2-m Cryostat (to test both magnets) 2-m long cryostat; 4 cryo- coolers; Loss-free He system • Existing 2-m cryostat (4K) at APS • Experience with SCU’s at APS • Each magnet to be tested in this cryostat 4 cryo- coolers 100-l LHe vessel magnet & beam pipe
SCU System Concept for LCLS-II HXU 0.5-m cold breaks 2-m long segments (+quad+BPM+PS) lu = 17-19 mm, Vacuum gap = 4-5 mm 5-m cryostats 500-W cryo-plant at 4 K Joel Fuerst, ANL
Summary • SCU technology promises a potential leap in FEL performance – needs development now • LCLS-II HXU can be extended to 7+ keV (1 MHz) and 1 TW (120 Hz) using the same SCU • R&D is underway – re-baseline of LCLS-II is possible, but depends on R&D and LCLS-II project schedule 1 MHz, 1 - 7+ keV 1 MHz 0.2-1.3 keV SXU SC-Linac or Cu-Linac HXU SCU switch 120 Hz, 1 - 25 keV, 1 TW (4 keV) 120 Hz Thanks to the SCU team: P.E., N. Holtkamp, H.-D. Nuhn, SLAC; C. Doose, J. Fuerst, Q. Hasse, Y. Ivanyushenkov, M. Kasa, G. Pile, E. Trakhtenberg, E. Gluskin, ANL; D. Arbelaez, J. Corlett, S. Myers, S. Prestemon, R. Schlueter, LBNL