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Nanobeam X-Ray scattering : probing matter at the nanoscale /

A comprehensive overview of the possibilities and potential of X-ray scattering using nanofocused beams for probing matter at the nanoscale, including guidance on the design of nanobeam experiments. The monograph discusses various sources, including free electron lasers, synchrotron radiation and ot...

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Bibliographic Details
Main Authors: Stangl, Julian
Group Author: Mocuta, Cristian; Chamard, Virginie, 1974; Carbone, Dina
Published: Wiley-VCH,
Publisher Address: Weinheim, Germany :
Publication Dates: [2014]
Literature type: eBook
Language: English
Subjects:
X-rays > Scattering
Nanophotonics
Nanoparticles
SCIENCE > Physics > Electricity
SCIENCE > Physics > Electromagnetism
Electronic books
Online Access: http://onlinelibrary.wiley.com/book/10.1002/9783527655069
Summary: A comprehensive overview of the possibilities and potential of X-ray scattering using nanofocused beams for probing matter at the nanoscale, including guidance on the design of nanobeam experiments. The monograph discusses various sources, including free electron lasers, synchrotron radiation and other portable and non-portable X-ray sources. For scientists using synchrotron radiation or students and scientists with a background in X-ray scattering methods in general.
Carrier Form: 1 online resource (xii, 270 pages) : illustrations
Bibliography: Includes bibliographical references (pages 245-264) and index.
ISBN: 1299863361
9781299863361
9783527655090
3527655093
3527410775
9783527410774
Index Number: QC482
CLC: O434.1
Contents: Nanobeam X-Ray Scattering; Contents; Foreword; Preface; 1 Introduction; 1.1 X-ray Interaction with Matter; 1.1.1 Transmission of X-ray; 1.1.2 Diffraction of X-rays; 1.1.3 X-ray Elemental Sensitivity; 1.2 Diffraction at Different Lengthscales and Real-Space Resolution; 1.2.1 How to Produce an X-ray Nanobeam; 1.2.2 Experiments with Nanobeams; 1.2.3 Coherence Properties of Small Beams; 1.2.4 Side Issues?; 1.3 Future Developments; 2 X-ray Diffraction Principles; 2.1 A Brief Introduction to Diffraction Theory; 2.1.1 Interference of X-ray Waves; 2.2 Kinematic X-ray Diffraction Theory.
2.2.1 The Structure Factor; 2.2.2 The Form Factor; 2.2.3 Reciprocal Lattice of Nanostructures; 2.2.4 The Phase Problem; 2.3 Reflectivity; 2.4 Properties of X-ray Beams; 2.5 A Note on Coherence; 2.5.1 Longitudinal Coherence and Wavelength Distribution; 2.5.2 Longitudinal Coherence Length; 2.5.3 Transverse Coherence and Thermal Sources; 2.5.4 Transverse Coherence Length; 2.6 X-ray Sources; 2.7 Diffraction Measurement: How to Access q in a Real Experiment; 2.7.1 Diffraction Geometries; 2.7.2 Lengthscales; 3 X-ray Focusing Elements Characterization; 3.1 Introduction and Context.
3.2 Refractive X-ray Lenses; 3.2.1 Characterization of Focusing Elements; 3.2.2 Spherical Refractive X-ray Lenses; 3.2.3 Parabolic Compound Refractive Lenses (CRL); 3.2.4 Kinoform Lenses; 3.2.5 Characteristics of the Refractive Lenses; 3.3 X-ray Mirrors. Reflection of X-rays at Surfaces; 3.3.1 Reflective X-ray Optics (Kirkpatrick-Baez Mirrors); 3.3.2 Capillaries; 3.3.3 Waveguides (Resonators); 3.3.4 Other Reflective Optical Elements; 3.4 Diffractive X-ray Optics; 3.4.1 Fresnel Zone Plates; 3.4.2 Hologram of a Point Object; 3.4.3 Quantities Characterizing a Binary Zone Plate.
3.4.4 Multilevel Zone Plate; 3.4.5 Getting a Clean and Intense Focused Beam with ZPs; 3.4.6 Bragg-Fresnel Lenses; 3.4.7 Multilayer Laue Lenses; 3.4.8 Photon Sieves; 3.4.9 Beam Compressors; 3.5 Other X-ray Optics; 3.6 Measuring the Size of the X-ray Focused Spot; 3.7 Conclusion; 4 Scattering Experiments Using Nanobeams; 4.1 From the Ensemble Average Approach towards the Single Nanostructure Study; 4.1.1 A Motivation for the Use of Small X-ray Beams; 4.1.2 Required Focused Beam Properties; 4.2 Scanning X-ray Diffraction Microscopy; 4.3 Finite Element Based Analysis of Diffraction Data.
4.4 Single Structure Inside a Device; 4.5 Examples from Biology; 4.6 Recent Experiments: The Current Limits; 4.6.1 Strain Distribution in Nanoscale Ridges; 4.6.2; Between Single Structure and Ensemble Average; 4.7 Outlook; 4.7.1 Experimental Developments; 5 Nanobeam Diffraction Setups; 5.1 Introduction; 5.2 Typical X-ray Diffraction Setup; 5.3 Nanodiffraction Setup Requirements; 5.3.1 Diffractometer; 5.3.2 Restriction of Setup; 5.3.3 Stability: How to Keep the Beam on the Sample; 5.3.4 Beating Drifts: More Solutions; 5.4 Nanobeam and Coherence Setup.

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