Performance of Small-Gap Undulators at the SLS Intermediate Energy Storage Ring Gerhard Ingold Paul Scherrer Institut Laboratory for Synchrotron Radiation FEMTO Group New Frontiers in Insertion Devices Satellite Workshop / XIV Users Meeting Sincrotrone Trieste November 20-21, 2006 G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 1
In Vacuum Undulators at SLS ( G. Ingold et al., SRI 2006, Korea, May 28 - June 2, 2006. ) G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 2
First In Vacuum Undulator Installed at SLS: U24 (in 2001) PSI/SPring-8 Collaboration G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 3
In Vacuum Undulators U24 Undulator: Magnetic Performance Measurement: 1st field integrals (flip coil), 2nd field integrals (hall probe) Phase error: 2.5 Optimization: magnet module swapping (T. Tanaka et al., NIM 465 (2001) 600.) New U19 undulator: specification according to U24 performance Decision: new undulators are ordered at companies who are responsible for magnetic measurements and optimization according to SLS specifications G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 4
Magnetic Specifications Experience: 4 in-vacuum undulators (and 5 polarized undulators) are operated during top-up operation. There is no indication any ID is limiting the dynamic aperture. G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 5
In Vacuum Undulators New: Short Period, Small Gap Undulator U19 Measured flux at 2.4 GeV & 8 kev: 8 10 ph/s/400 ma/0.01% bw (gap: 6 mm) [Installed at 4 beamlines: XAS/FEMTO, PX-I, PX-II, csaxs] G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 6
In Vacuum Undulators 2.4 GeV & High Harmonic Operation: Undulator Radiation 4-18 kev The SLS became the first medium energy user facility to rely on the high harmonic operation of small gap, short period undulators to reach 18 kev Independent of the vendor (Sumitomo/Neomax undulators according to SLS specifications Danfysik) all devices are high performing G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 7
Small Gap Operation Risk of Radiation Damage U24 measured spectrum (7th harmonic): no indication of radiation damage No change in spectral performance: 3.5 years of operation (ca. 2.5 years in top-up mode) Magnet: NEOMAX-32EH (not the most resistive material, see Bizen et al., SPring-8) G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 8
Magnet Materials 3 different magnet materials used: check possible radiation damage by spectral performance G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 9
Impact on e-beam orbit & XBPM-calibration X06SA-FE-BM1:X [µm] X06SA-FE-BM1:Y [µm] 800 600 400 200 0-200 -400-600 h4a #28 [-0.2:0.2] mm 1st order polynomial fit (a=-2.246) 1st order polynomial fit (a=-2.214) -800-260 -220-180 -140-100 -60-20 20 60 100 140 180 220 260 800 600 400 200 0-200 -400-600 ARIDI-BPM-05:X-AVG [µm] v4a #28 [-0.2:0.2] mm 1st order polynomial fit (a=-4.401) -800-60 -40-20 0 20 40 60 80 100 120 140 160 180 200 220 240 260 ARIDI-BPM-05:Y-AVG [µm] (a) FF and FOFB corrections switched off: change of local BPM readings with gap (b) XBPM calibration: linear dependence on parallel e-beam displacement in the undulator G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 10
In Vacuum Undulators X-Ray Beam Pointing Stability 1 rad ID ID feedforward (ID-FF) scheme using X-ray beam position monitors (XBPMs). 110 100 X-BPM X, X-BPM FB off, FF off X-BPM Y, X-BPM horizontal FB off, FF off X-BPM X, X-BPM FB off, FF on X-BPM Y, X-BPM FB off, FF on X-BPM X, X-BPM FB on, FF on X-BPM Y, X-BPM FB on, FF on * FOFB ON, IDFF ON, XBPM FB ON FOFB ON 70 60 X06SA-FE-BM1:X [µm] 90 80 70 FOFB ON, IDFF ON FOFB ON, IDFF ON 50 40 30 X06SA-FE-BM1:Y [µm] + FOFB ON, IDFF ON, XBPM FB ON 60 FOFB ON 20 vertical 50 6.5 7 7.5 8 8.5 9 9.5 10 10.5 11 11.5 12 10 X06SA-ID-GAP:READ [mm] FOFB and ID-FF corrections: residual motion 1 m (8.6 m distance from source point). G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 11
In Vacuum Undulators Undulator Construction: Vendor & PSI Vendor (NEOMAX DANFYSIK): mechanics, magnetics (+ mag. measurements), vacuum PSI: vacuum (taper transitions), electrics, control, alignment (mover), diagnostic+interlock G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 12
Undulator Magnetic Measurements: Stretched & Pulsed Wire Magnetic measurements after delivery: 1st & 2nd integral (stretched wire) and trajectory straightness (pulsed wire) G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 13
In Vacuum Undulators U19 In-Vac Undulator: Installion at the SLS Storage Ring In-situ alignmnent ( 50 m): undulator installed on mover system Gap-reading: linear encoders (shielded) attached to the outer backing beam G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 14
In Vacuum Undulators U19 Undulators: Mechanical Precision - Gap Taper Measurement of mechanical gap taper (linear vs. rotary encoder), specified: 5 m Achieved (for 3 IDs) with 1-motor operation (optional: 2-motor operation for taper 1 m) G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 15
Flexible Taper Transitions Failure concerning in-vac undulator operation at SLS in 5 years: 2 water failures Critical: pipes for internal water-cooling; flexible taper (leak developed, reason unknown) G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 16
Conclusions In-vacuum undulators are a proven technology High harmonic operation at intermediate energy storage rings is a valid concept No radiation damage has been observed (under conditions of top-up operation) High performance (hybrid) in-vac undulators are commercially available Next step at SLS: cryogenic in-vac undulator to replace high field, short period wiggler G. Ingold / New Frontiers in Insertion Devices, Trieste, Nov 20-21, 2006. 17