First Group of SSRF Beamlines

1. First Group of SSRF Beamlines Xu HongjieSep. 25, 2001 Shanghai Shanghai Synchrotron Radiation Facility SSRF

2. 1、Introduction Short story • In April, 1995, the CAS and SMG agreed in principle to make joint efforts for a proposal to construct the SSRF in Shanghai. • In June, 1995, a working group to carry out the feasibility study of the SSRF was set up by the CAS. • In 1995, project team (then called working group) started holding the symposiums to discuss what the users need and which kind of beamline the first group should contain ( over 100 users from about 50 universities, institutes and companies). Shanghai Synchrotron Radiation Facility SSRF

3. Requiements and suggestions • SSRF should be a advanced third generation synchrotron radiation facility. • SSRF should be a user's facility (alignment with user's requirements and needs). • Their shold be enough (?) beamlines meet requirements and needs of users. Beamline allocation models cover the spectrum from FOOB's to PRT/CAT's . Shanghai Synchrotron Radiation Facility SSRF

4. The research lifetime must be longer than 20-30 years after its establishment. • Proposed rules for choosing first group beamlines  Advanced beanline --- tomorrow  Popular beamline --- today Social impact and industry application Shanghai Synchrotron Radiation Facility SSRF

5. Soliciting the proposals • In March, 1996, Working group sent out a anouncement to 58 universities and institutes all over China to solicit the proposals of first group beamlines of SSRF. • Announcement (in Chinese). • The fifteen beamnlines were proposed as candidates (Table 1). • Only 5 to 7 beamlines (including 2-3 insertion devices) will be constructed in the first phase of construction. Shanghai Synchrotron Radiation Facility SSRF

6. Announcement for Soliciting Proposal of Beamlines and Design March 1996 Shanghai Synchrotron Radiation Facility SSRF

7. Proposal Beamlines to users for Soliciting Design March 1996 Shanghai Synchrotron Radiation Facility SSRF

8. By the end of 1997, Around 70 proposal came from more than 20 Universities And Institutes. • The proposals receivedwere concerned with seventeen beamlines. • Distribution of the proposed beamlines Shanghai Synchrotron Radiation Facility SSRF

9. Shanghai Synchrotron Radiation Facility SSRF

10. Shanghai Synchrotron Radiation Facility SSRF

11. Shanghai Synchrotron Radiation Facility SSRF

12. …… Important scientific issuses which require UV radiation have decreased in number compared to those which require hard x-rays ( Birgenau-Shen's Report, 1997). • New tendency: use of coherence/ Micro focus for hard x-ray / Inelastic scattering / Molecular Environment Science (MES) /Infrared---. • Energy of SSRF storage will increase to 3.5 Gev from (2.2 -2.5) GeV in 1998. Shanghai Synchrotron Radiation Facility SSRF

13. Dec.24-25, 1998, a symposium was held to discuss the proposals received, about 130 users who submitted proposals attended the symposium. • Based on the through discussion in the symposium, the Science and Technology Committee (STC) of SSRF chose seven plus one from twenty one beamlines proposed (four more proposals) as the first group beamlines. Shanghai Synchrotron Radiation Facility SSRF

14. Proposed first group beamlines Macromolecular Crystallography XAFS High Resolution Diffraction and Scattering Medical Application Hard X-ray Micro focus and Application Soft X-ray coherent microscopyLIGA Shanghai Synchrotron Radiation Facility SSRF

15. Proposed substitute beamlines • X-ray scattering • Multi-usage soft X-raymicro-spectroscopy • Photoelectron spectroscopy • Infrared Shanghai Synchrotron Radiation Facility SSRF

16. Review meeting • During June 10 – 17, 1999, the domestic review meeting had been held to review the conceptual design of the first group beamlines of SSRF • Almost all main users of the first group beamlines have been invited and most of them attended the meeting • The advising group, 5 - 7 user experts for each beamline , joint the design and construction of beamline Shanghai Synchrotron Radiation Facility SSRF

17. International SSRF Beamline CDR Review Meeting with the participation of 18 experts from the USA, Japan, Germany, France, Italy and Britain had been held during Oct. 21-23, 1999. • Very positive appraisal on the design of the seven beamlines as well as many valuable suggestions for approvement. • Further improvement of CDR design in accordance with these suggestions has been taken. Shanghai Synchrotron Radiation Facility SSRF

18. 2. First Group Beamlines Shanghai Synchrotron Radiation Facility SSRF

19. Macromolecular Crystallography Beamline Scientific applications: • Structural determination of macromolecules and their complexes like membrane protein, nucleic acid, viruses and drugs etc.. • *Time-resolved structural studies of intermediates of biological processes with lifetime down to sub-nanoseconds. Experimental methods: • MAD and related energy-dispersive methods. • Single and multiple isomorphous replacement. • * White beam Laue diffraction. Shanghai Synchrotron Radiation Facility SSRF

20. Beamline Design : Source: wiggler, N=20, u=7.5cm, Bmax=1.25T monochromatic beam: • wavelength range: 0.6–2  • wavelength resolution: ~ 210-4 • focused beam size(FWHM): 0.14 0.2~ 0.20.35mm2 • flux at sample : 1012 ~ 1013 ph/s • focused beam divergence: 1~5mrad (horizontally) 0.1~0.5mrad (vertically) *white beam: • spectral range: 0.5 –3 • focused beam size: 0.20.4mm2 • flux at sample: ~ 1014 ph/s 0.1%bw ~ 1010 ph/bunch Shanghai Synchrotron Radiation Facility SSRF

21. Slits collimating-mirror monochromator focusing-mirror White beam End-station (reserved) End-station Layout of Macromolecular Crystallography beamline Shanghai Synchrotron Radiation Facility SSRF

22. XAFS Beamline Scientific applications : Provide structural information on a variety of materials, like catalysts, metalloproteins, environmental contaminants etc. • Mainly for general purpose XAFS • Possible for other measurements, like diffraction and scattering XAFS with different detection geometry • transmission XAFS • Fluorescence XAFS • surface XAFS Shanghai Synchrotron Radiation Facility SSRF

23. Shanghai Synchrotron Radiation Facility SSRF

24. Collimating-mirror Monochromator Focused mirror Experiment station Layout of XAFS beamline Shanghai Synchrotron Radiation Facility SSRF

25. High Resolution Diffraction and Scattering Beamline Scientific applications: • Crystalline structure of powder samples; • The structures of thin films, multi-layer films and one dimensional superlattice materials; • The structures of surfaces, near surfaces and interfaces; • Crystalline structure of small single-crystal molecules; • Structural phase transition; • The structures and properties of microparticle system and porous materials; • The structures of catalysts, polymers and biological macromolecules; • Point defects and defect clusters in solid samples; • The structures of amorphous materials, liquid crystals and liquid metals. Shanghai Synchrotron Radiation Facility SSRF

26. Beamline Design : • Source: bending magnet • Energy range: 4~30 keV • Accepttance: 3 mrad(H)0.15 mrad(V) • Energy resolution: <2  10-4 (Si(311) monochromator) <4  10-4 (Si(111) monochromator) • Focusing spot size: ~0.5(H)0.5(V) mm2, 3.0(H)0.2(V) mrad2 • Photon flux at sample position: >1011 photons/s (Si(111) monochromator) Shanghai Synchrotron Radiation Facility SSRF

27. High Resolution Diffraction and ScatteringBeamline layout 1 2 3 4 1 5 1. Collimating mirror; 2. Sagittally focusing double crystal monochromator; 3. Vertically focusing mirror; 4. Six-circle goniometer; 5. Imaging plate. Shanghai Synchrotron Radiation Facility SSRF

28. Hard X-Ray Micro Focus Beamline • Scientific Applications: • Providing a X-ray beam in the energy range of 4—40keV for: • Micro x-ray fluorescence (m-XRF), permits non-destructive trace-element analysis with micron resolution and sub-ppm sensitivity. • Micro x-ray absorption spectroscopy (m-XAS), provides unique chemical information on oxidation state, coordination state, and local environment. • Micro x-ray diffraction (m-XRD), permits, for example, structure determinations and the mapping of strain in interconnects on semiconductor chips. • Computed x-ray microtomography (m-XCT), can be used for examining the internal microstructure of materials. Shanghai Synchrotron Radiation Facility SSRF

29. Beamline Design: Bending magnet Energy range (unfocused): 4—40keV (focused monochromatic): 4—34keV energy resolution (E/E): <210-4 Spot size at sample: 1—10 micron, adjustable Photon flux at sample: >109photons/(m2s0.1%bw) Shanghai Synchrotron Radiation Facility SSRF

30. collimating mirror DCM toroidal mirror K-B mirrors Layout of Hard X-Ray Micro Focus Beamline Shanghai Synchrotron Radiation Facility SSRF

31. Medical Application Beamline Scientific Applications: ( Aimed at the studies of different sort of medical imaging techniques:) • Intravenous coronary angiography • Other applications as mammography, CT of the brain, micro-beam radiation therapy Shanghai Synchrotron Radiation Facility SSRF

32. Schematic beamline set-up Source: wiggler, N=10, u=13.6cm, Bmax=1.8T Key component: Bent Laue crystal monochromator Flux at patient position: 7 1011 phs/s  mm2 Shanghai Synchrotron Radiation Facility SSRF

33. Layout of medical application beamline Shanghai Synchrotron Radiation Facility SSRF

34. Soft X-ray Coherent Microscopy Beamline • Scientific Applications: Polymers, Biomaterials, and Soft Matter • Organic Earth Materials • Engineering Polymers • Surfaces and Interfaces Techniques: • STXM (Scanning transmission X-ray miroscopy) • XANES (X-ray Absorption Near Edge Structure) Shanghai Synchrotron Radiation Facility SSRF

35. Design Goals: • Wavelength range： 250~750 eV, cover K edges of C, N, O, F ，L edge of Ca ， L edges of transition element up to Fe • Spatial resolution：50~150 nm • Spectral resolution: (E/DE): 3000 • Flux output：109 (photons/s/0.1%BW) Shanghai Synchrotron Radiation Facility SSRF

36. Entrance slit Toroidal mirror Optical Set-up for coherent microscopy beamline Shanghai Synchrotron Radiation Facility SSRF

37. 1. CF63 gate valve 2. laser collimating system 3. BPM 4. Water cooled four knife diagram 5.vacuum gear 6. plane mirror 7. g-ray collimator 8. vacuum pipe 9. bellow 10.ion pump 11. torroidal mirror 12. water-cooled entrance slit 13. monochromator 14. Exit slit 15. end station Layoutof coherent microscopybeamline Shanghai Synchrotron Radiation Facility SSRF

38. LIGA Beamline Scientific Applications: To develop the techniques of micro-fabricating for microstructures and micro-parts, such as micro-motor, micro-pump, fiber connector, sensors and gratings etc.. Design goals: Source: bending magnet Accepting angle horizontal: 4 mrad; vertical: 0.4 mrad Energy range: 1- 8keV Spot size (horizontal): 120 mm Scanning range (vertical): 110 mm Shanghai Synchrotron Radiation Facility SSRF

39. Layout of LIGA Beamline Layout of the experimental station Shanghai Synchrotron Radiation Facility SSRF

40. New Requirments from Users • A symposium on using SSRF dedicated to front research area had been held during Dec. 21-23, 2000 • Many active scientists attend the symposium, whose topics distribute widely • Life Science, Geometry Science, Nano Science and technology, Medical, Chemical Industry and basic research topics. • First group of beamlines has to been modifying based on the requirements of users. Shanghai Synchrotron Radiation Facility SSRF

41. Shanghai Synchrotron Radiation Facility SSRF

42. Tasks: Structural Genomics Program Genome Analysis & Target Selection Expression, purification of proteins Crystallization NMR data collection Beamline data collection Structure Solving Computational 上海光源！？ PDB Experimental Models, folds, functional Analysis

43. Dynamic Theoretical Method Quantum dynamics Molecular dynamics Langevin Hopping kinetics, Lattice process 1fsec 1psec 1nsec 1sec 1sec Ultrafast Spectroscopy Optical,Vibrational Measurement Dielectric, Magnetic ,Mechanical relaxation Chemical reaction Shanghai Synchrotron Radiation Facility SSRF

44. 3. R&D of Beamlines • Cooling • Monochromator • Mirror • Bender • Components Shanghai Synchrotron Radiation Facility SSRF

45. Front end of Undulator Beamline Shanghai Synchrotron Radiation Facility SSRF

46. BPM of CVD Diamond • 光束测量分辨率5m；光束位置检测误差<6m； Shanghai Synchrotron Radiation Facility SSRF

47. Cooling Experimental System • 功率密度1.28W/mm2；晶面形变量0.08m Shanghai Synchrotron Radiation Facility SSRF

48. Long Trace Profiler Prototype • 扫描范围0~350mm；单点稳定性0.2mrad/200s Shanghai Synchrotron Radiation Facility SSRF

49. Sagittal Monochromator • 晶体调节精度0.45 ； • 聚焦光斑水平弥散25%；可承受最大热负载~1W/mm2 Shanghai Synchrotron Radiation Facility SSRF

50. Water Cooling Slits • 定位精度<7m；重复精度 2m Shanghai Synchrotron Radiation Facility SSRF