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Highlights of science of USR Yuhui Dong BSRF, IHEP, CAS 2012/10/29
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The emitance of storage ring 1GLS 3GLS ERL/Diff. limited storage ring
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Coherence of X-ray The spatial (transverse) coherent of light: 4 · · ´= where : the size of light source; ´ : the divergence of light source; : the wavelength. If the source is small enough (point source), or the divergence is small enough (parallel beam), then we obtain coherent light.
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The improvement of storage rings 1GLS emitance ~100nmrad, coherent wavelength: 1256nm Coherent length (transverse) at sample @1Å X-ray: L t ~500nm. 3GLS (SSRF) emitance: 4nmrad, coherent wavelength: 50nm L t ~5mm 3GLS (NSLS-II) 1nmrad, 12.56nm L t ~20mm ERL 0.1nmrad, 1.256nm Diffraction limit ring (SPring-8 upgrading plan) 10pmrad, 1.256Å
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Longitude (temporal) coherence Longitude coherence is related to energy resolution: L c = 2 / 1Å X-ray, / =10 -4, L c =10 4 Å; / =10 -7, L c =10 7 Å. Usually the longitude coherent length is enough for structure determination.
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The key point: emitance Low emitance source = coherent X-ray source The only available source now: X-FEL Maybe diffraction limit storage ring or ERL?
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e-gun: 1mmrad Linac: 1nmrad ( =10 6 ) Undulator: slicing, ~10pmrad 4 · · ´= 4 ·10pm=1.256Å Pictures from Dr. Zhirong Huang, LCLS
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Comparison between XFEL and USR XFELUSR Pulse intensity10 11 -10 12 phs/pulse10 4 -10 5 phs/pulse (not totally coherent, every wave pocket ~3phs) Pulse duration~100fs~10ps Coherent flux in a pulse10 24 -10 25 phs/s10 15 -10 16 phs/s Average coherent flux10 13 -10 14 phs/s (100Hz)10 12 -10 13 phs/s (~100MHz)
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The possible scientific cases of USR Nano- or Meso-Scale Science Techniques Diffraction: diffraction of single nano-object. Imaging (CDI): imaging of meso-scale structures (3~5nm) without lens XPCS: dilute samples, better time-resolution
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Diffraction of nano-tube 10,000 cps 1250 cps Single molecule Single atom Au dopant Calculated Diffraction Patterns Pictures courtesy Dr. Chi-Chang Kao, SLAC
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CDI: Resolution vs. intensity 1mm size sample 10 12 phs 3~5nm reso. 1s collecting time Required intensity: 10 21 -10 22 phs/s/mm 2 /mrad 2 /0.1%BW@sour ce 10 20 phs/mm 2 @s ample, 1 m spot size
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Three-Dimensional Visualization of a Human Chromosome Using Coherent X-Ray Diffraction 38nm resolution structure of chromosome Coherent x-ray diffraction microscopy is an ideal form of x-ray phase-contrast imaging, since there is no contrast degradation due to lenses Disadvantage : TEM: the sample must be thinned Confocal microscopy: the sample must be labeled with fluorescent dyes Advantage : Due to the absence of resolution limiting optics and the penetrative ability of X-rays, Coherent X-Ray Diffraction technique ultimately offers new insights into the structure of intact, three- dimensional (3D) biological specimens. PRL 102, 018101 (2009)
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Coherent X-ray diffraction imaging of strain at the nanoscale Visualization of strain inside a Pb nanocrystal. CDI, resolution ~30nm Nature material,vol 8,2009
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Three-dimensional imaging of strain in a single ZnO nanorod Nature material,vol 9,2010 CDI of ZnO nanorod. The strain field can be reconstructed.
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CDI and XPCS Time plot Dynamic Picture courtesy Prof. John Miao and Dr. Aymeric Robert Coherence of X-ray
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XPCS at USR Signal-to-noise ratio of XPCS is proportional to the square of the coherent flux. (Falus et al., JSR 2006) USR ~10 times of coherent flux Dilute samples become possible Faster dynamic studies become possible (~10ns)
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The requirement for hard X-ray For basic research, brilliance up to 10 21 - 10 22 phs/s/mm 2 /mrad 2 /0.1%BW is necessary. For industrial materials, hard X-ray (energy up to 300keV) is necessary.
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BSRF (2.5GeV, 1GLS) HLS (0.8GeV, 2GLS) The SR facilities in mainland of China Hard X-ray is required. SSRF (3.5GeV, 3GLS)
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The importance of hard X-ray Penetrative ability: 300keV X-ray, 10cm Al or 2cm steel, real workpiece. High resolution: atomic resolution at nm range. Real matter, Real conditions, Real time High energy storage ring is needed.
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Summary For the requirement of basic research AND industrial material studies, the future SR facility in China should provide: Brilliance of 10 21 - 10 22 phs/s/mm 2 /mrad 2 /0.1%BW Focus spot can reach to 1mm (for diffraction, CDI) or 10nm (for nano-probe) Photon energy up to 300keV More ID as possible.
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Thank you for your attention
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