Stability Requirements for Superconducting Wiggler Beamlines

Slides:



Advertisements
Similar presentations
X-rays Long Wave IR Visible UV X-rays Gamma rays wavelength (nm) Frau Röntgen's hand.
Advertisements

Focusing monochromators/analyzers Asymmetric diffraction geometry of the monochromator Dispersive double crystal monochromator Two wavelength sandwich.
NSLS-II Stability Workshop – User Requirements Working Group – Day 1 Stability Requirements for soft x-ray coherent microscopy/imaging -- C. Jacobsen :
The waves spread out from the opening!
Short bunches in SPEAR J. Safranek for the SPEAR3 accelerator group November 2, 20101J. Safranek CLS THz Workshop.
X-ray sources Sealed tubes - Coolidge type common - Cu, Mo, Fe, Cr, W, Ag intensity limited by cooling req'ments (2-2.5kW) Sealed tubes - Coolidge type.
Flash Spectroscopy using Meridionally- or Sagittally-bent Laue Crystals: Three Options Zhong Zhong National Synchrotron Light Source, Brookhaven National.
Synchrotron Radiation Sources and Optics
Stanford Synchrotron Radiation Lightsource Sources and Optics for XAS Apurva Mehta.
(0,0) RECIPROCAL LATTICE (0,1) (1,1) (2,1) (3,1) REAL LATTICE a b a* b*
1 BROOKHAVEN SCIENCE ASSOCIATES National Synchrotron Light Source II Damping Wiggler Beamline: XAS Preliminary Design Summary Paul Northrup January 16th,
MENA3100, 3/2-10, OBK X-ray diffractionXRD Røntgendiffraksjon Single crystalPowder.
M. Hücker Manipulating Competing Order with High Pressure Neutron Scattering Group (CMPMS) Correlated Electron Systems ( Superconductivity, Magnetism,
X-Ray Diffraction ME 215 Exp#1. X-Ray Diffraction X-rays is a form of electromagnetic radiation having a range of wavelength from nm (0.01x10 -9.
J. B. Hastings LUSI DOE Review July 23, 2007 X-ray Optics 1 X-ray Optics J. B. Hastings Beam definition Attenuators Slits Pulse picker.
Chapter 25 Waves and Particles Midterm 4 UTC
Sources and Beam Lines of Canadian Light Source Emil Hallin Canadian Light Source (material organized and presented by D.T. Jiang)
Progress on the New High Intensity Cold Neutron Spectrometer, MACS C. Broholm 1,2, T. D. Pike 1,2, P. K. Hundertmark 1,2, P. C. Brand 2, J. W. Lynn 2,
Effective lens aperture Deff
Synchrotron Powder Diffraction Simplified: Introducing the Advanced Photon Source’s dedicated high-resolution beamline 11-BM Matthew Suchomel, Brian Toby,
GSECARS Update 13-BM-C Side Station Scientific programs is DAC diffraction and surface science Proposed partial funding as COMPRES Infrastructure Project.
Chapter 12 Atomic X-Ray Spectroscopy
Introduction to Synchrotron Radiation Instrumentation
Beamline A – Joint Engineering, Environment and Processing Beamline ( JEEP ) Alexander Korsunsky Department of Engineering Science University of Oxford.
Environmental Sciences Department BNL Environmental Sciences Dept. and EnviroSuite: from NSLS to NSLS-II Jeff Fitts July 18, 2007 Environmental Research.
1 BROOKHAVEN SCIENCE ASSOCIATES Lonny Berman and Dario Arena, NSLS Summary The present built-out NSLS-II design includes: 30 bending magnet ports, each.
June 14th 2005 Accelerator Division Overview of ALBA D. Einfeld Vacuum Workshop Barcelona, 12 th -13 th September 2005 General 10 th September 2005.
1 BROOKHAVEN SCIENCE ASSOCIATES Hard X-Ray Wiggler Sources at NSLS-II Oleg Chubar X-ray source scientist, XFD, NSLS-II Workshop on Preparation of High-Pressure.
June 14th 2005 Accelerator Division Overview of ALBA D. Einfeld Vacuum Workshop Barcelona, 12 th -13 th September 2005 General 10 th September 2005.
BROOKHAVEN SCIENCE ASSOCIATES BIW ’ 06 Lepton Beam Emittance Instrumentation Igor Pinayev National Synchrotron Light Source BNL, Upton, NY.
CLS Status Update E. Matias Canadian Light Source.
PHYS 430/603 material Laszlo Takacs UMBC Department of Physics
Sept.2001 Shanghai symposium D.T. Jiang Acknowledgements Deming Shu, APS Tom Rebedeue, SSRL.
The Development of Laue Monochromator at X17B3 National Synchrotron Light Source in (111) diffraction intensities by severer of non-bending Si.
1 BROOKHAVEN SCIENCE ASSOCIATES Experimental Facilities John Hill Director, NSLS-II Experimental Facilities Division NSLS-II User Workshop July 17, 2007.
X-Ray Measurement Methods From Chapter 6 of Textbook 2 and other references Diffractometer Hull/Debye-Scherrer method Pinhole method Laue Method Rotating.
The waves spread out from the opening!
Assessing Single Crystal Diamond Quality
1 BROOKHAVEN SCIENCE ASSOCIATES NSLS II: Accelerator System Overview NSLS II Advisory Committees October 18/19, 2006 Satoshi Ozaki.
1 Data Acquisition What choices need to be made?.
November 14, 2004First ILC Workshop1 CESR-c Wiggler Dynamics D.Rubin -Objectives -Specifications -Modeling and simulation -Machine measurements/ analysis.
1 Proposal for a CESR Damping Ring Test Facility M. Palmer & D.Rubin November 8, 2005.
X-ray powder diffractometer X-ray powder diffractometer.
1 BROOKHAVEN SCIENCE ASSOCIATES NSLS-II Overview Satoshi Ozaki Director, Accelerator Systems Division NSLS-II Project March 27, 2007.
ELECTRON MOVING AT CONSTANT VELOCITY
The Muppet’s Guide to: The Structure and Dynamics of Solids XRD.
Proposed NSLS X13B Microdiffraction Instrument Source & Optics James M. Ablett National Synchrotron Light Source.
Parameters of the new diffractometer “ARES” Aleksey E. Sokolov PNPI NRC “KI”
1 BROOKHAVEN SCIENCE ASSOCIATES NSLS II: the Accelerator System Briefing Experimental Facilities Advisory Committee May 10, 2007 Satoshi Ozaki Director,
1 BROOKHAVEN SCIENCE ASSOCIATES Lonny Berman EFAC May 10 th 2007 ID Beamline Optics and Damping Wigglers.
MCNSI meeting, February 2006 Contents: People –V. Ryukhtin left for part time only Multichannel focusing benders – continuation –resolution functions.
NMI3 meeting, ISIS, September 26-29, 2005 Contents: Overview of new capabilities of the RESTRAX software Numerical optimizations of TAS parameters Virtual.
A New High Intensity Cold Neutron Spectrometer at NIST J. A. Rodriguez 1,3, P. Brand 3, C. Broholm 2,3, J.C. Cook 3, Z. Huang 3, P. Hundertmark 3, J. Lynn.
X-Ray Diffraction Spring 2011.
Texture analysis of geological materials experimentally deformed at high p and T Florian Heidelbach Bayerisches Geoinstitut University of Bayreuth Texture.
1 BROOKHAVEN SCIENCE ASSOCIATES A Wiggler Beamline for XAS at NSLS-II Paul Northrup NSLS-II Project and Environmental Sciences Department Brookhaven National.
An electron/positron energy monitor based on synchrotron radiation. I.Meshkov, T. Mamedov, E. Syresin, An electron/positron energy monitor based on synchrotron.
1 BROOKHAVEN SCIENCE ASSOCIATES 1 NSLS-II Lattice Design 1.TBA-24 Lattice Design - Advantages and shortcomings Low emittance -> high chromaticity -> small.
Cont. Proteomics Structural Genomics Describes the experimental and analytical techniques that are used to determine the structure of proteins and RNA.
ID11 beamline Multipurpose beamline for diffraction experiments
SSRL Beam Line Infrastructure Update February 2002
CLS Status Update E. Matias Canadian Light Source June 8, 2018
Visit for more Learning Resources
Introduction to Synchrotron Radiation
Diffraction Literature:
Instrumentation systems
The Storage Ring Control Network of NSLS-II
Crystal and X-ray Diffraction
Optics John Arthur, SLAC & William W. Craig, LLNL April 24, 2002
The waves spread out from the opening!
Presentation transcript:

Stability Requirements for Superconducting Wiggler Beamlines Zhong Zhong

NSLSII SCW Design Magnet Peak Field B0 : 6 T 3.5 T Period Length λ: 6 cm 6 cm Number of Main Poles (N) : 29 29 number of end poles 4 4 Wiggler Length (L): 0.87 m 0.87 m Critical Energy EC (0.665BE2): 36 keV 21 keV Deflection Parameter ( K=0.93B0λ ): 33.6 19.5 Radiated Power at 500mA (3.9B02LI ): 61 kW 21 kW Fan size (2K/): 11.4 milli-radians 6.7 milli-radians Ampli. e- oscillation (X0= λw K/(γπ)) 0.11 mm 0.063 mm horiz. beam chamber aperture (mm) ? ? vert. beam chamber aperture (mm) 10 10 magnetic (iron) gap (mm) 15 15 Table I: specifications of the 6 T wiggler and the alternative 3.5 T wiggler Facility Manufacturer Field(T) Period (cm) # full-field poles NSLS X17 Oxford 6 17.4 5 BESSY II Novosibirsk 7 14.8 13 CLS Novosibirsk 4.2 4.8 25 ELETTRA Novosibirsk 3.6 6.4 45 MAX lab ? 3.5 6.1 47 Table  II. A partial list of working super-conducting wigglers similar in specifications

NSLSII SCW Performance Flux of the NSLS-II superconducting wiggler, compared with that of NSLS-II bending magnets, damping wigglers, and an alternative superconducting wiggler (W60 in NSLS-II CD0 proposal) with 3.5 T peak field.

Sagittal focusing tunable Laue monochromator NSLSII SCW Beamlines Beamline Optics & Instrumentation: 2 fixed-wavelength side stations and 2 center stations, white beam or focused monochromatic beam, or both 6-circle Huber diffractometer with bent Laue analyzer for high-resolution diffraction experiments. Center Hutches Side Hutches 2-D focusing sagittally bent Laue monochromator Sagittal focusing tunable Laue monochromator Vertical focusing mirror

NSLSII SCW Experimental Programs Angular dispersive x-ray diffraction (ADXD) Large volume press Diamond Anvil cell Diffuse scattering Powder diffraction Energy-dispersive x-ray diffraction (EDXD) Strain mapping Imaging and radiation therapy research Diffraction Enhanced Imaging Microbeam Radiation Therapy

ADXD, large samples First crytal Second Crystal large volume press, diffuse scattering, powder diffraction, sample size ~ 1 mm. x-rays are focused by a sagittal focusing Laue monochromator at a magnification of approximately unity. A position stability of 10% of sample size results in a source-position stability of approximately 100 µm horizontally and vertically. Vertical angular stability: 10 µrad A wavelength stability of 10-4 Si 111 monochromator at a Bragg angle of approximately 0.1 rad Sagittal bending enables sagittal-focusing Anticlastic bending Allows meridional focusing Lattice strain increases integrated reflectivity by 1-2 orders of magnitude compared to perfect crystal

EDXD Strain mapping, deformation experiments, diamond anvil cell, large volume press Most challenging for orbit stability: use the peak position as a figure-of-merit. Angle of the incident beam is defined by a fixed slit and the source Diffraction angle (2) typically being 0.1 rad. To obtain 10 micro-strains (10-5 d/d) accuracy, the incident angle as defined by the slit and source should be maintained to within 10-6 rad. The source and beam-defining slit being 50 meters apart, the vertical source position should have a stability of 5010-6 meters, or 50 µm.

ADXD, small samples Diamond anvil cell, sample size: a few microns Source position stability of 100 µm horizontally and vertically. K-B mirrors (at a magnification of approximately 100:1) are used to focus the x-rays. A position stability of 1 µm at the sample Vertical angular stability: 10 µrad A wavelength stability of 10-4 Si 111 monochromator at a Bragg angle of approximately 0.1 rad

Imaging and radiation therapy DEI and micro-CT, micro-beam radiation therapy (MRT) The distance between the subject and detector is typically 1 meter, and a resolution of ~1 µm is typically desirable. 50 meters source-to-subject distance, The source position should be stable to within 50 µm horizontally and vertically. Synchrotron Beam Double Crystal Monochromator Object Detector Analyzer Synchrotron DEI Setup Synchrotron Radiography

Summary: superconducting wiggler The source position should be stable within 50 µm horizontally and vertically Source vertical angle should be stable within about 10 µrad. There is no requirement on source horizontal angle due to the large horizontal divergence afforded by a superconducting wiggler.