Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Atomic Resolution Imaging of Carbon Nanotubes from Diffraction Intensities J.M. Zuo 1, I.A. Vartanyants 2, M. Gao 1, R. Zhang 3, L.A.Nagahara 3 1 Department.

Published byMervin Edwards Modified over 9 years ago

Similar presentations

Presentation on theme: "1 Atomic Resolution Imaging of Carbon Nanotubes from Diffraction Intensities J.M. Zuo 1, I.A. Vartanyants 2, M. Gao 1, R. Zhang 3, L.A.Nagahara 3 1 Department."— Presentation transcript:

1 1 Atomic Resolution Imaging of Carbon Nanotubes from Diffraction Intensities J.M. Zuo 1, I.A. Vartanyants 2, M. Gao 1, R. Zhang 3, L.A.Nagahara 3 1 Department of Materials Science and Engineering, UIUC 2 Department of Physics, UIUC 3 Physical Sciences Research Lab., Motorola Labs Science 300, 1419 (2003)

2 2 Carbon Nanotubes (atomic structure) c=na 1 +ma 2, c – wrapping vector, a 1, a 2 – unit vectors n=m – ‘armchair’ m=0 – ‘zigzag’ STM images of single-walled nanotubes J. Wildoer, et al, Science, 391, 59 (1998).

3 3 Carbon Nanotubes (imaging) Structure: A – armchair B - zigzag C – chiral Imaging: D – STM image of 1.3 nm SWNT (J. Wildoer et al., Science 391, 59 (1998)) E – TEM image of MWNT F – TEM micrograph of 1.4 nm SWNTs in a bundle (A. Thess et al., Science 273, 483 (1996) G – SEM image of MWNTs grown as a nanotube forest

4 4 Coherent Nano-Area Electron Diffraction Schematic ray diagram CL – condenser lens CA – condenser aperture FP – front focal plane OL – objective lens D – imaging plates

5 5 Electron Scattering on Carbon Nanotubes Weak phase object – kinematic scattering Transmission function Diffracted intensity: For constant illumination:  (r)=const

6 6 Electron wavefront on the sample 10  m aperture C s and  f – spherical aberration and defocus of electron lens

7 7 Electron Diffraction pattern from SWNT Scattering amplitude for SWNT: Simulated diffraction pattern (n 1, n 2 )=(14, 6) d=1.39 nm,  =17.0º M. Gao, J.M. Zuo et al., Appl. Phys. Lett (2003) Experiment diffraction pattern d=1.40±0.02 nm,  =17.0º(±0.2º)

8 8 Iterative phase retrieval algorithm sk(x)sk(x)Ak(q)Ak(q) Reciprocal Space Constraints A'k(q)A'k(q)s'k(x)s'k(x) Real Space Constraints FFT FFT -1 Real space constraints: finite support real, positive Reciprocal space constraint: R.W.Gerchberg & W.O. Saxton, Optic (1972) 35, 237 J.R. Fienup, Appl Opt. (1982). 21, 2758 R.P. Millane & W.J. Stroud, J. Opt. Soc. Am. (1997) A14, 568

9 9 Reconstruction of SWNT from simulated data Simulated diffraction patternReconstructed Image

10 10 Model for SWNT (d=1.39 nm,  =17º)

11 11 Reconstruction of SWNT Experimental Diffraction PatternReconstructed Diffraction Pattern

12 12 Reconstructed Image of SWNT

13 13 Far-field diffraction pattern from DWNT Pixel resolution 0.025 1/nm

14 14 1d reconstruction from DWNT Equatorial dataReconstructed electron density

15 15 Electron Diffraction Pattern from DWNT ExperimentReconstruction

16 16 Reconstructed Image of DWNT

17 17 Reconstructed Image and model of DWNT Model Outer tube: (n 1,n 2 )=(35,25) d 1 =4.09 nm Inner tube: (n 1,n 2 )=(26,24) d 2 =3.39 nm

18 18 Possible Applications I.Imaging of biological molecules ferritine, actines, radiation damage II.Imaging of nanostructures nanowires nanoclusters

Download ppt "1 Atomic Resolution Imaging of Carbon Nanotubes from Diffraction Intensities J.M. Zuo 1, I.A. Vartanyants 2, M. Gao 1, R. Zhang 3, L.A.Nagahara 3 1 Department."

Similar presentations

Scanning near-field optical microscopy (SNOM) for magneto-optics Paolo Vavassori INFM - National Research Center on nanoStructures and Biosystems at Surfaces.

Scanning near-field optical microscopy (SNOM) for magneto-optics Paolo Vavassori INFM - National Research Center on nanoStructures and Biosystems at Surfaces.
Reference Bernhard Stojetz et al. Phys.Rev.Lett. 94, (2005)

Reference Bernhard Stojetz et al. Phys.Rev.Lett. 94, (2005)
Mechanisms of Terahertz Radiation Generation in Graphene Structures Institute for Nuclear Problems, Belarus State University, Belarus The XII-th International.

Mechanisms of Terahertz Radiation Generation in Graphene Structures Institute for Nuclear Problems, Belarus State University, Belarus The XII-th International.
Electronic Structure Carbon nanotubes possess large π -electronic systems similar to planar graphene 1 Reduced dimensionality around the circumference.

Electronic Structure Carbon nanotubes possess large π -electronic systems similar to planar graphene 1 Reduced dimensionality around the circumference.
Electron Optics Basic Introduction Bob Ashley 6-14-2013.

Electron Optics Basic Introduction Bob Ashley
Transmission Electron Microscopy (TEM)

Transmission Electron Microscopy (TEM)
What is diffraction? Diffraction – the spreading out of waves as they encounter a barrier.

What is diffraction? Diffraction – the spreading out of waves as they encounter a barrier.
IPC Friedrich-Schiller-Universität Jena 1 2. Contrast modes in light microscopy: Bright field.

IPC Friedrich-Schiller-Universität Jena Contrast modes in light microscopy: Bright field.
Fire Protection Laboratory Methods Day

Fire Protection Laboratory Methods Day
1 Ultrafast Electron Diffraction from Molecules in the Gas Phase Martin Centurion University of Nebraska – Lincoln.

1 Ultrafast Electron Diffraction from Molecules in the Gas Phase Martin Centurion University of Nebraska – Lincoln.
CNT – Characteristics and Applications

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

Single Particle X-ray Diffraction - the Present and the Future John Miao Stanford Synchrotron Radiation Laboratory Stanford Linear Accelerator Center.
Quantum liquids in Nanoporous Media and on Surfaces Henry R. Glyde Department of Physics & Astronomy University of Delaware National Nanotechnology Initiative.

Quantum liquids in Nanoporous Media and on Surfaces Henry R. Glyde Department of Physics & Astronomy University of Delaware National Nanotechnology Initiative.
Electron Microscope. Light Resolution  The resolution of a microscope is limited by the diffraction of light. Single diffractionSingle diffraction 

Electron Microscope. Light Resolution  The resolution of a microscope is limited by the diffraction of light. Single diffractionSingle diffraction 
Magnificent Optical Properties of Noble Metal Spheres, Rods and Holes Peter Andersen and Kathy Rowlen Department of Chemistry and Biochemistry University.

Magnificent Optical Properties of Noble Metal Spheres, Rods and Holes Peter Andersen and Kathy Rowlen Department of Chemistry and Biochemistry University.
Using Atomic Diffraction to Measure the van der Waals Coefficient for Na and Silicon Nitride J. D. Perreault 1,2, A. D. Cronin 2, H. Uys 2 1 Optical Sciences.

Using Atomic Diffraction to Measure the van der Waals Coefficient for Na and Silicon Nitride J. D. Perreault 1,2, A. D. Cronin 2, H. Uys 2 1 Optical Sciences.
Brookhaven Science Associates U.S. Department of Energy JEOL TEM/STEM course 2010F FasTEM University of Michigan 27 – 29 June 2006 Robert Klie Center for.

Brookhaven Science Associates U.S. Department of Energy JEOL TEM/STEM course 2010F FasTEM University of Michigan 27 – 29 June 2006 Robert Klie Center for.
STED: Nanoscale 3D Optical Imaging Digvijay Raorane & Arun Majumdar Department of Mechanical Engineering Department of Materials Science University of.

STED: Nanoscale 3D Optical Imaging Digvijay Raorane & Arun Majumdar Department of Mechanical Engineering Department of Materials Science University of.
Nanoparticle Polarizability Determination Using Coherent Confocal Microscopy Brynmor J. Davis and P. Scott Carney University of Illinois at Urbana-Champaign.

Nanoparticle Polarizability Determination Using Coherent Confocal Microscopy Brynmor J. Davis and P. Scott Carney University of Illinois at Urbana-Champaign.
I. K. Robinson, SSRL Imaging Workshop, October 20021 Phasing of Three Dimensional Diffraction Patterns from Finite-Sized Objects Ian Robinson Ivan Vartanyants.

I. K. Robinson, SSRL Imaging Workshop, October Phasing of Three Dimensional Diffraction Patterns from Finite-Sized Objects Ian Robinson Ivan Vartanyants.

Similar presentations

Ads by Google