1 / 17

MAX IV Undulators Performance

MAX IV Undulators Performance. H. Tarawneh On behalf of the ID Group. 1. Outlook:. Insertion Devices @ MAX IV. Soft X rays: APPLE II undulators Hard X rays: In-vacuum Insertion Devices Undulators Performance. 2. List & Status of IDs @ MAX IV.

letitiah
Download Presentation

MAX IV Undulators Performance

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. MAX IV UndulatorsPerformance H. Tarawneh On behalf of the ID Group

  2. 1 Outlook: • Insertion Devices @ MAX IV. • Soft X rays: APPLE II undulators • Hard X rays: In-vacuum Insertion Devices • Undulators Performance

  3. 2 List & Status of IDs @ MAX IV *) Built by collaboration with SOLEIL synchrotron *) Built by industry *) Built in-house *) Transfer from MAX-II ring (characterized at MAX IV ID magnet lab)

  4. 3 APPLE II Undulators @ MAX IV • In-house design, assembly and characterization of undulators is key to meet tight requirements of MAX IV Accelerators & Beamlines. • In-house measurement systems: Hall probe bench (5.5 m), flip coil & Stretched wire • Work force for building 6 APPLE II & refurbish 2 ID from MAX II ring. • New Pulsed wire system- construction ongoing. 3 GeV Ring APPLE II λu=53 mm & L= 4 m Gap=17.5mm Circular Polarization: Gap=12.5mm

  5. 4 APPLE II Undulators @ MAX IV • In-house design, assembly and characterization of undulators is key to meet tight requirements of MAX IV Accelerators & Beamlines. • In-house measurement systems: Hall probe bench (5.5 m), flip coil & Stretched wire • Work force for building 6 APPLE II & refurbish 2 ID from MAX II ring. • New Pulsed wire system- construction ongoing. 3 GeV Ring Induced kick APPLE 48 mm, L=4m All helical mode (gap vs.phase) RMS orbit distortion (x/y) of 6.4 μm &7.6 μm @ gap 20 mm APPLE II 53mm

  6. 5 APPLE II Undulators @ MAX IV • In-house design, assembly and characterization of undulators is key to meet tight requirements of MAX IV Accelerators & Beamlines. • In-house measurement systems: Hall probe bench (5.5 m), flip coil & Stretched wire • Work force for building 6 APPLE II & refurbish 2 ID from MAX II ring. • New Pulsed wire system- construction ongoing. 3 GeV Ring APPLE II λu=53 mm & L= 4 m APPLE II λu=48 mm & L= 4 m FWHM 5.6 eV 20 mm gap 30x30 μrad2 Calculated spectra is based On magnetic measurement data

  7. 6 APPLE II Undulators @ MAX IV • In-house design, assembly and characterization of undulators is key to meet tight requirements of MAX IV Accelerators & Beamlines. • In-house measurement systems: Hall probe bench (5.5 m), flip coil & Stretched wire • Work force for building 6 APPLE II & refurbish 2 ID from MAX II ring. • New Pulsed wire system- construction ongoing. 1.5 GeV Ring Quasi - APPLE II λu=84 mm & L= 2.7 m

  8. 7 HIPPIE EPU53 GUI Envelope on gap vs. phase. Min. 250 eV for all polarizations

  9. 8 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. • Minimum vertical acceptanceof 1.1 mm.mrad is defined by the off-centeredMAX-IV IV wiggler.Physical gap of 4.5 mm @ βy=4m. (BSC/lifetimerequirementsonly). • Impedance budget vs. Long buncheswith 100 MHz RF system. 3 GeV ring BaselineLattice

  10. 9 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. 2 IVUs for BioMAX & NanoMAXbeamlines, λu=18mm, Lengthof 2 m and Keff=1.95 (Achieved Keff=2.19 for BioMAX and Keff=2.10 for NanoMAX at 4.2 mm magnetic gap). BioMAX: Measuredphaseerror Kicks seen by beam

  11. 10 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. BioMAXundulator, Period length 18 mm Length 2 meters, Min. gap 4.2 mm Spectra with lengthened bunches

  12. 11 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. NanoMAX@ gap 4.3mm and taper of 0.10 mm. Tapering feature @ NanoMAX & BioMAX λu=18mm, Length of 2 m. 5% of peak field per meter. BioMAX IVU 200 μm gap difference @ 7th harmonic& 5mm gap

  13. 12 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. Displacement scan of the electron beam orbit at 5 mm gap, 10 mA inside NanoMAX IVU. The 7th harmonic energy is monitored for different offset values. Measurements indicates -20 μmvertical offset is needed. Photon beam-based alignment

  14. 13 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. Undulatorradiationstructure from BALDER wiggler. (small emittance) BALDER IVW built by SOLEIL , λu=50 mm, Lengthof 2 m and Keff=9

  15. 14 In-vacuum ID’s @ MAX IV • Highbrilliance, hard x-rayssourcesarebased on roomtempratureand short period In-vacuum undulatorswith hybrid structure @ 3 GeV ring and Short PulseFacility. Tapering & beamlinecontrol over the electronbeamorbit. BALDER IVW built by SOLEIL , λu=50 mm, Lengthof 2 m and Keff=9

  16. Future IDs @ MAX IV 15 • Cryo-cooled (77 K) undulatorsfor Phase-III beamlines at MAX IV. MedMAX beamline Energy range: 12 – 40 keV DiffMAX beamline Energy range: 3 – 50 keV Half-period structure design • Features exist ONLY @ MAX IV worldwide ( ̴2022). • Ultra low emittance (0.2-0.3 nm.rad) as brilliance and coherence source. • Long electron bunches leading to low heat load budget on low gap cryo-cooled core of undulator. • Available straight section to test & ultimately operate short period undulator. • Use of 2nd harmonic to cover wider energy range (e.g. DiffMAX).

  17. 16 Special thanks go to: Thomas Ursby ConnySåthe Pedro F. Tavares Konstantin Klementiev Ulf Johansson Thank You

More Related