Small Angle Scattering - Introduction

Similar documents
X-ray, Neutron and e-beam scattering

Chapter 12. Nanometrology. Oxford University Press All rights reserved.

Scattering Techniques and Geometries How to choose a beamline. Christopher J. Tassone

Introduction to X-ray and neutron scattering

introduction to SAXS for polymers -a user view-

Cross Section and Line Edge Roughness Metrology for EUV Lithography using Critical Dimension Small Angle X-ray X

Chapter 10. Nanometrology. Oxford University Press All rights reserved.

Nanoindentation for Characterizing Wood & Related Systems

SCI. Scientific Computing International. Scientific Computing International. FilmTek. Raising Thin Film Metrology Performance to a New Level

MEMS Metrology. Prof. Tianhong Cui ME 8254

Imaging Methods: Scanning Force Microscopy (SFM / AFM)

Scattering by a Multi-Electron Atom, Atomic Scattering Factors; Wave Propagation and Refractive Index

POLARISATION. We have not really discussed the direction of the Electric field other that that it is perpendicular to the direction of motion.

CHEM-E2105. Wood and Wood Products

The Solid State. Phase diagrams Crystals and symmetry Unit cells and packing Types of solid

Features of static and dynamic friction profiles in one and two dimensions on polymer and atomically flat surfaces using atomic force microscopy

2.76/2.760 Multiscale Systems Design & Manufacturing

3.012 Structure An Introduction to X-ray Diffraction

Silver Thin Film Characterization

Small Angle X-ray Scattering (SAXS)

Soft Matter Studies with X-rays

5. Building Blocks I: Ferroelectric inorganic micro- and nano(shell) tubes

Introduction to SAXS at SSRL

Fibrillated Cellulose and Block Copolymers as a Modifiers of Unsaturated Polyester Nanocomposites

Lecture 2 Atomic Structure. Dr. Firas Farhan

Diamond. There are four types of solid: -Hard Structure - Tetrahedral atomic arrangement. What hybrid state do you think the carbon has?

There are four types of solid:

MPIP-Mainz. FORTH Heraklion. T.Still,W.Cheng,N.Gomopoulos G.F G.F. Sculpture by E.Sempere (Madrid)

MS482 Materials Characterization ( 재료분석 ) Lecture Note 5: RBS

Mechanical characterization of single crystal BaTiO 3 film and insitu. XRD observation of microstructure change due to

Study of Block Copolymer Lithography using SCFT: New Patterns and Methodology

Coherent X-ray diffraction for Condensed matter physics

Atomic Force Microscopy (AFM) Part I

Crystal planes. Neutrons: magnetic moment - interacts with magnetic materials or nuclei of non-magnetic materials. (in Å)

Surface Sensitive X-ray Scattering

The ideal fiber pattern exhibits 4-quadrant symmetry. In the ideal pattern the fiber axis is called the meridian, the perpendicular direction is

Especial Bump Bonding Technique for Silicon Pixel Detectors

Fadei Komarov Alexander Kamyshan

Micromachining structured optical fibres using focused ion. beam (FIB) milling

29 May 2015 Carbon Nanotube Based Detectors for THz Radiometry

A NEW SMALL ANGLE X-RAY SCATTERING TECHNIQUE FOR DETERMINING NANO-SCALE PORE/PARTICLE SIZE DISTRIBUTIONS IN THIN FILM

Elastic and Inelastic Scattering in Electron Diffraction and Imaging

What is the role of simulation in nanoscience research?

The Photonic Band Gap and Colloidal Crystals. Focus: Photonic Band Gap

THE EFFECTS OF ADDING 1 M NaOH, KOH AND HCl SOLUTION TO THE FRAMEWORK STRUCTURE OF NATURAL ZEOLITE

Photonic Crystals. Introduction

CBE Science of Engineering Materials. Scanning Electron Microscopy (SEM)

The goal of this project is to enhance the power density and lowtemperature efficiency of solid oxide fuel cells (SOFC) manufactured by atomic layer

Make sure the exam paper has 9 pages (including cover page) + 3 pages of data for reference

Fabrication of micro-optical components in polymer using proton beam micro-machining and modification

Providing sustainable supply of clean water is one of

Make sure the exam paper has 7 pages (including cover page) + 3 pages of data for reference

CELLULOSE NANOWHISKER OBTAINED FROM COTTON REJECTED BY TEXTILE INDUSTRY

SOLID STATE 9. Determination of Crystal Structures

Techniques for directly measuring the absorbance of photoresists at EUV wavelengths

Nanostructures Fabrication Methods

LOW-TEMPERATURE Si (111) HOMOEPITAXY AND DOPING MEDIATED BY A MONOLAYER OF Pb

CHEM 681 Seminar Mingqi Zhao April 20, 1998 Room 2104, 4:00 p.m. High Resolution Transmission Electron Microscopy: theories and applications

Determining Protein Structure BIBC 100

A one-dimensional model for small-angle X-ray scattering from crystalline block copolymers

Highly piezoelectric, thermal stable ferroelectrets from cyclic olefin copolymer. Yan Li, Hui Wang, Changchun Zeng ANTEC 2015, Orlando

COST MP0601 Short Wavelength Laboratory Sources

Physical Chemistry of Polymers (4)

Fig. 1: Raman spectra of graphite and graphene. N indicates the number of layers of graphene. Ref. [1]

Structural Characterization of Giant Magnetoresistance Multilayers with New Grazing Incidence X-ray Fluorescence

Kavli Workshop for Journalists. June 13th, CNF Cleanroom Activities

IN THE NAME OF ALLAH, THE MOST MERCIFUL AND COMPASSIONATE

One-Dimensional Uniform Array. Linear Array Principle of Operation

Atomic and Nuclear Physics

Structural evolutions in electroactive poly(vdf-co-trfe) copolymers for organic electronics

disordered, ordered and coherent with the substrate, and ordered but incoherent with the substrate.

Perpendicular MTJ stack development for STT MRAM on Endura PVD platform

EV Group. Engineered Substrates for future compound semiconductor devices

Pre-lab Quiz/PHYS 224. Your name Lab section

Methoden moderner Röntgenphysik II Streuung und Abbildung

Supplementary Figure 1 Scheme image of GIXD set-up. The scheme image of slot die

Supplementary Figure 1 SEM images and corresponding Fourier Transformation of nanoparticle arrays before pattern transfer (left), after pattern

Strukturbestimmung mit Streumethoden

Self Organization. Order. Homogeneous state. Structurally ordered state. Structurally ordered state. Order. Disorder

Photolithography 光刻 Part II: Photoresists

X-ray Diffraction. Diffraction. X-ray Generation. X-ray Generation. X-ray Generation. X-ray Spectrum from Tube

Supporting Information

Chapter 12 - Modern Materials

Summary Chapter 2: Wave diffraction and the reciprocal lattice.

Immersed diffraction gratings for the Sentinel-5 earth observation mission. Ralf Kohlhaas

MSN551 LITHOGRAPHY II

Low Voltage Field Emission SEM (LV FE-SEM): A Promising Imaging Approach for Graphene Samples

Transmission Electron Microscopy for metrology and characterization of semiconductor devices

Physics 208 Exam 1 Oct. 3, 2007

The first three categories are considered a bottom-up approach while lithography is a topdown

Scattering Lecture. February 24, 2014

Optical Measurements of Critical Dimensions at Several Stages of the Mask Fabrication Process

Photomasks. Photolithography Evolution 9/11/2004 ECE580- MPE/MASKS/PHOTOMASKS.PPT

Surface and line-edge roughness in solution and plasma developed negative tone resists: Experiment and simulation

Title of file for HTML: Supplementary Information Description: Supplementary Figures and Supplementary References

Surface Sensitivity & Surface Specificity

Etching Capabilities at Harvard CNS. March 2008

The vibrational spectroscopy of polymers

High Yield Structured X-ray Photo-Cathode Development and Fabrication

AXIOMATIC DESIGN OF MULTI-SCALE SYSTEMS

Transcription:

Small Angle Scattering - Introduction Why scattering at small angles? Angle & size related thru Braggs law: λ = 2d sin θ

Small Angle Scattering - Introduction Why scattering at small angles? Angle & size related thru Braggs law: λ = 2d sin θ Suppose CuKα x-rays (λ = 1.5418 Å) calculate 2θ for various ds

Small Angle Scattering - Introduction Why scattering at small angles? Angle & size related thru Braggs law: λ = 2d sin θ Suppose CuKα x-rays (λ = 1.5418 Å) calculate 2θ for various ds d 2θ q 10 Å (0.001 micron) 8.84 0.628 Å -1 50 Å 1.77 100 Å (0.01 micron) 0.88 0.0628 Å -1 300 Å 0.29 600 Å 0.15 1000 Å (0.1 micron) 0.09 0.00628 Å -1 10,000 Å (1 micron) 0.009 0.000628 Å -1

Small Angle Scattering - Introduction d 2θ q = (4π/λ) sin θ = 2π/d 10 Å (0.001 micron) 8.84 0.628 Å -1 50 Å 1.77 100 Å (0.01 micron) 0.88 0.0628 Å -1 300 Å 0.29 600 Å 0.15 1000 Å (0.1 micron) 0.09 0.00628 Å -1 10,000 Å (1 micron) 0.009 0.000628 Å -1 High-angle x-ray scattering (usually ~2-160 2θ) --> atomic scale structure

Small Angle Scattering - Introduction d 2θ q = (4π/λ) sin θ = 2π/d 10 Å (0.001 micron) 8.84 0.628 Å -1 50 Å 1.77 100 Å (0.01 micron) 0.88 0.0628 Å -1 300 Å 0.29 600 Å 0.15 1000 Å (0.1 micron) 0.09 0.00628 Å -1 10,000 Å (1 micron) 0.009 0.000628 Å -1 High-angle x-ray scattering (usually ~2-160 2θ) --> atomic scale structure Small-angle scattering --> structure of BIG things

WAXS and SAXS study of (m)tmxdi-pdms siloxane-urethaneureas

WAXS and SAXS study of (m)tmxdi-pdms siloxane-urethaneureas Hard segments --> regions with crystal-like order Soft segments --> amorphous siloxane chains

WAXS and SAXS study of (m)tmxdi-pdms siloxane-urethaneureas Saxs scattering curves for various NCO/OH ratios (a = 1.5/1; e = 4.5/1): 0.9 Size of the hard segment crystalline regions changes

Microstructure orientation and nanoporous gas transport in semicrystalline block copolymer membranes Polymer sheets of semicrystalline ethylene (E)/ethylene propylene (EP) diblock E/EP and triblock E/EP/E copolymers made by channel die proessing

Microstructure orientation and nanoporous gas transport in semicrystalline block copolymer membranes Polymer sheets of semicrystalline ethylene (E)/ethylene propylene (EP) diblock E/EP and triblock E/EP/E copolymers made by channel die processing Sheets are stacked into several types of blocks w/ different gas transport props.

Microstructure orientation and nanoporous gas transport in semicrystalline block copolymer membranes Polymer sheets of semicrystalline ethylene (E)/ethylene propylene (EP) diblock E/EP and triblock E/EP/E copolymers made by channel die processing CD FD 145 Å 436 Å saxs image for perpendicular texture type

Nanometer to Micrometer Void Microstructure Characterization of SOFC Layers and Interfaces by Small Angle Scattering (SAXS) and Computed X-ray Microtomography(XMT)

Critical Dimension Metrology of Nanoscale Structures with Small Angle X-ray Scattering NIST developing transmission saxs method capable of angstrom level precision in critical dimension evaluation over (50 x 50) mm arrays of nanoscale periodic structures

Critical Dimension Metrology of Nanoscale Structures with Small Angle X-ray Scattering SEM image of a photoresist grating on a silicon wafer & resulting 2-D SAXS image

Critical Dimension Metrology of Nanoscale Structures with Small Angle X-ray Scattering SEM image of a photoresist grating on a silicon wafer & resulting 2-D SAXS image Streaks tell about deviations from ideal grating & defects such as long wavelength line edge roughness

Critical Dimension Metrology of Nanoscale Structures with Small Angle X-ray Scattering (a) blue rectangles represent etched regions in a film (b) resulting SAXS detector image

The measurement of the micro-fibril angle in soft-wood Wood cell wall consists of bundles of a crystalline arrangement of cellulose chains (microfibrils)

The measurement of the micro-fibril angle in soft-wood Wood cell wall consists of bundles of a crystalline arrangement of cellulose chains (microfibrils) Microfibrils align quite parallel in a spiral around cell wall, with spiral axis along long cell direction MFA X α

The measurement of the micro-fibril angle in soft-wood Typical saxs patterns from Norway spruce - mean MFA of 20 - longitudinal cell axis vertical. (c) pattern recorded at α = 0. (d) pattern recorded at α = 45

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback