Chris Hall Monash Centre for Synchrotron Science Monash University, Melbourne, Australia.

Slides:

Advertisements

Similar presentations

A Crash Course in Radio Astronomy and Interferometry: 4

Advertisements

Lecture 11. Microscopy. Optical or light microscopy involves passing visible light transmitted through or reflected from the sample through a single or.

1 SpectroscopIC aNALYSIS Part 7 – X-ray Analysis Methods Chulalongkorn University, Bangkok, Thailand January 2012 Dr Ron Beckett Water Studies Centre &

1. Detector 2. Crystal diffraction conditions

Interference and Diffraction

Detectors for imaging macro-molecules at atomic resolution JP Abrahams, Biophysical Structural Chemistry, Leiden University With thanks to: Jules Hendrix,

Groups: WA 2,4,5,7. History  The electron microscope was first invented by a team of German engineers headed by Max Knoll and physicist Ernst Ruska in.

Ultrafast XUV Coherent Diffractive Imaging Xunyou GE, CEA Saclay Director : Hamed Merdji.

January 2004 Chuck DiMarzio, Northeastern University ECEU692 Subsurface Imaging Course Notes Part 2: Imaging with Light (1) Profs. Brooks and.

Synchrotron applications of pixel and strip detectors at Diamond Light Source Julien Marchal, Nicola Tartoni, Colin Nave Diamond Light Source 03/09/2008.

1 Extreme Ultraviolet Polarimetry Utilizing Laser-Generated High- Order Harmonics N. Brimhall, M. Turner, N. Herrick, D. Allred, R. S. Turley, M. Ware,

Optical Tweezers F scatt F grad 1. Velocity autocorrelation function from the Langevin model kinetic property property of equilibrium fluctuations For.

Bachelor of Nanotechnology / Bachelor of Science La Trobe University.

Research Opportunities at LCLS September 2011 Joachim Stöhr.

Imaging x-ray generation and Scattering Tabletop soft x-ray coherent imaging microscopes.

Properties of Multilayer Optics An Investigation of Methods of Polarization Analysis for the ICS Experiment at UCLA 8/4/04 Oliver Williams.

Single Particle X-ray Diffraction - the Present and the Future John Miao Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center.

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.

Signal Analysis and Processing for SmartPET D. Scraggs, A. Boston, H Boston, R Cooper, A Mather, G Turk University of Liverpool C. Hall, I. Lazarus Daresbury.

Keith A. Nugent ARC Centre of Excellence for Coherent X-ray Science & School of Physics The University of Melbourne Australia Coherent X-ray Science: Coherence,

ELECTROMAGNETIC RADIATION

UCLA The X-ray Free-electron Laser: Exploring Matter at the angstrom- femtosecond Space and Time Scales C. Pellegrini UCLA/SLAC 2C. Pellegrini, August.

Do it with electrons !. Microscopy Structure determines properties We have discussed crystal structure (x-ray diffraction) But consider now different.

4-1 Chap. 7 (Optical Instruments), Chap. 8 (Optical Atomic Spectroscopy) General design of optical instruments Sources of radiation Selection of wavelength.

Common types of spectroscopy

Protein Structure Determination Part 2 -- X-ray Crystallography.

Lesson 5 Conditioning the x-ray beam

Effective lens aperture Deff

Demolding ENGR Pre Lab.

BROOKHAVEN SCIENCE ASSOCIATES BIW ’ 06 Lepton Beam Emittance Instrumentation Igor Pinayev National Synchrotron Light Source BNL, Upton, NY.

X-Ray Reflection Data Analysis Update Information can be extracted from XRR data: - Film thickness - Roughness.

Coherent X-ray Diffraction Workshop, BNL, May Keith A. Nugent ARC Centre of Excellence for Coherent X-ray Science & School of Physics The University.

FEMTOSECOND LASER FABRICATION OF MICRO/NANO-STRUCTURES FOR CHEMICAL SENSING AND DETECTION Student: Yukun Han MAE Department Faculty Advisors: Dr. Hai-Lung.

PHYS 430/603 material Laszlo Takacs UMBC Department of Physics

1 2. Focusing Microscopy Object placed close to secondary source: => strong magnification The smaller the focus, the sharper the image! Spectroscopy, tomography.

John Miao Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center Crystallography without Crystals and the Potential of Imaging Single.

Engr College of Engineering Engineering Education Innovation Center Engr 1182 Nano Pre-Lab Demolding Rev: 20XXMMDD, InitialsPresentation Short.

Reaching the Information Limit in Cryo- EM of Biological Macromolecules: Experimental Aspects -Robert M. Glaeser and Richard J. Hall (2011)

SEM Scanning Electron Microscope

The SPARX FEL Project a source for coherent radiation production in the soft X-ray energy range.

Atomic structure model

Coherent X-ray Diffraction (CXD) X-ray imaging of non periodic objects.

Using Technology to Study Cellular and Molecular Biology.

Electron Microscope. How do they work Instead of using light they fire a beam of electrons (which have a wavelength less than 1nm compared to light which.

Taikan SUEHARA, ATF2 meeting, KEK, 2006/11/22 Status of fringe stabilization of Shintake-monitor Taikan SUEHARA The University of Tokyo.

3D-ASICS for X-ray Science

Fourier transform from r to k: Ã(k) =  A(r) e  i k r d 3 r Inverse FT from k to r: A(k) = (2  )  3  Ã(k) e +i k r d 3 k X-rays scatter off the charge.

For off-center points on screen, Fresnel zones on aperture are displaced …harder to “integrate” mentally. When white and black areas are equal, light at.

Summer '07 at CLS Small Angle X-Ray Scattering Peter ChenChithra Karunakaran & Konstantine Kaznatcheev.

Freezing phase scheme for complete-field characterization and coherent control of femtosecond optical pulses Jung Y. Huang, Ci L. Pan, and J. I. Chyi An.

Highlights of science of USR Yuhui Dong BSRF, IHEP, CAS 2012/10/29.

Do it with electrons !. Microscopy Structure determines properties We have discussed crystal structure (x-ray diffraction) But consider now different.

Page 1 Phase Determination by Creative BiostructureCreative Biostructure.

The Electromagnetic Spectrum High Harmonic Generation

1. Detector 2. Crystal diffraction conditions

L. Glover(1,3), R. DeSalvo(1,3), B. Kells(2), I. Pinto(3)

RECONSTRUCTED CELL STRUCTURE Jakob Andreasson

R. Hashimoto, N. Igarashi, R. Kumai, H. Takagi, S. Kishimoto

Determining a Detector’s Saturation Threshold

Photo acoustic tomography

Protein Structure Determination

Diffraction T. Ishikawa Part 1 Kinematical Theory 1/11/2019 JASS02.

Review calculation of Fresnel zones

Scalar theory of diffraction

Val Kostroun and Bruce Dunham

Types of Microscopy Type Probe Technique Best Resolution Penetration

Iterative Phase Retrieval (Jianwei Miao & David Sayre)

Computed Tomography (C.T)

Active Pixel Sensors for Electron Microscopy

Presentation transcript:

Chris Hall Monash Centre for Synchrotron Science Monash University, Melbourne, Australia.

Imaging small things  Light microscopy limited by penetration Limited by wavelength (100s nm)  Electron microscopy Has to be done under vacuum Exquisite resolution (0.2 nm)  X-ray microscopy Difficult to focus the x-rays 15 nm is a very good resolution

Crystallography and coherent diffractive imaging (CXDI)  X-ray crystallography Details down to 0.1 nm…but only with crystals.  CXDI - Microscopy without lenses Use the coherence of the illuminating light to obtain structural information. All the advantages of x-ray microscopy, but much higher resolution (<10 nm)

The Goals of CXDI  Imaging single (large) proteins  Eventually use an x-ray free electron laser  Collect an image of the sample (protein)…before it is blown apart.  More modest goals…small biological entities (cells). 70 nm

CXDI …how does it work? Axioms:  If the waves incident on the object are plane waves. Then in the far field, after interacting with the object the wave represents a Fourier Transform of the object.  To get back to an image of the object you simply need to perform an inverse Fourier transform.  In light optics the lens does this.

Detection and reconstruction  If we can detect the complex far field wave we can do the FT -1 with a computer.  The problem is that our detectors only detects intensity. No phase information is measured directly.  However, the phase can be estimated then refined by iteration.

Fourier transforms Frequency Intensity F Phase

Gershberg-Saxton (and family)

CXDI for real J. Miao, K. O. Hodgson, T. Ishikawa, C. A. Larabell, M. A. LeGros and Y. Nishino, Proceedings of National Academy of Science of the USA 100, (2003)

Fresnel CXDI

Fresnel CDI

Where will it happen APS, Illinois, USA AS, Victoria, Australia

So, what are the current detector requirements? In the geometry used now: Energy range for > 50% DQE = 0.5 – 4 keV Dynamic range in image (noise to saturation) >10 7 Pixel size ideally < 25  m Pixel number >1024 x 1024 Maximum local count rate 10 4 per pix per second

Trade study CriterionEssentialDesirable 1Dynamic range Pixelation 2048 x 2048>4096 x >4096 3Pixel Size <100  m< 50  m 4Energy Range 0.5 keV to 3 keV 5Detective Quantum Efficiency 10%50% 6Rate Capability > 10 4 / pixel/ second> 10 6 / pixel/ second 7Frame rate 1 Hz1 kHz 8Vacuum compatibility bar10 -6 bar 9Dead time fraction 10%1% 10Parallax error < 1 pixel at 20 degrees 11Gaps in FOV AcceptableNone

Commercially available detectors  Easy option, but…  Not designed for our purposes

XFEL pulse structure 100 msecs 600  secs Up to 30,000 pulses 100 fsecs 10 4 photons, incident on the sample 99.4 msecs

Thank you for your attention Thanks to my colleagues at MCSS and the CXS Prof. Rob Lewis (MCSS) Prof. Keith Nugent (Melbourne University) Prof. Andrew Peele (La Trobe University) Dr. Garth Williams (Melbourne University) Dr. Mark Pfeiffer (La Trobe University) Evan Curwood (Monash University) Mr. Andrew Berry (Monash University) Dr. Wilfred Fullagar (Monash University) The Australian Research Council fund the Centre of Excellence in Coherent X-ray Science.

Results so far Gold blobs on Si 3 N 4 substrate

Specifications for the CXS End Station apparatus  Includes a 4 axis laser Doppler displacement meter which provides: Positioning of sample w.r.t beam of 30 nm Resolution in closed loop feedback of 0.2 nm =>Stability of sample w.r.t. beam of 2 nm