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|b eng
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|d OCLCQ
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|a 804664467
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|a 9780123978141
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|a 0123978149
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|a 9780123944221
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|a 0123944228
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|a (OCoLC)801979189
|z (OCoLC)804664467
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|a QH212.X2
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|a SCI
|x 047000
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|a 502.82
|2 23
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|a TEFA
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|a Neutron and x-ray microscopy.
|n Part 1 /
|c by Jay Theodore Cremer, Jr.
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|a 1st ed.
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|a Amsterdam ;
|a Boston :
|b Elsevier/Academic Press,
|c 2012.
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|a 1 online resource.
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|a text
|b txt
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|a computer
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|a online resource
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|a Advances in imaging and electron physics ;
|v v. 172
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|a Title from PDF title page (viewed on July 27, 2012).
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|a Includes bibliographical references and index.
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|a This special volume of Advances in Imaging and Electron Physics details the current theory, experiments, and applications of neutron and x-ray optics and microscopy for an international readership across varying backgrounds and disciplines. Edited by Dr. Ted Cremer, these volumes attempt to provide rapid assimilation of the presented topics that include neutron and x-ray scatter, refraction, diffraction, and reflection and their potential application. Key features: * Contributions from leading authorities * Informs and updates on all the latest developments in the field.
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|a Front cover; Advances in Imaging and Electron Physics: Neutron and X-ray Microscopy -- Part 1; Copyright; Table of Contents; Foreword; Preface; Contributor; Future Contributions; 1 Introduction to Neutron and X-ray Optics; 1. Compound Refractive Lenses for Neutrons and X-rays: Background and Theory; 1.1. The Compound Refractive Lens; 1.2. The Neutron and X-ray Complex Refractive Index; 1.3. Biconcave Parabolic and Spherical Lenses: Transmission and Aperture; 1.4. CRL Resolution Comparison with Pinhole.
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|a 1.5. Optical System Analysis with Kirchhoff Equation: Mathematical Expression of Huygen's Principle1.6. Neutron and X-ray Reflection; 1.7. Light Microscopy Archetypes for Neutron and X-ray Microscopy; 1.8. Neutron and X-ray Microscopes: Amplitude-Contrast Microscopes and Phase-Contrast Microscopes; 1.9. Neutron and X-ray Temporal and Longitudinal Spatial Coherence Length, and Transverse Spatial Coherence Length; 1.10. Neutron and X-ray Fresnel Zone Plates; 1.11. Neutron and X-ray Achromat Lenses Using Fresnel Zone Plate and Compound Refractive Lens.
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|a 1.12. Neutron and X-ray Fresnel and Compound Fresnel Lenses1.13. Neutron and X-ray Monochromator with Compound Refractive Lens and Pinhole; 1.14. Comparison of Neutron, X-ray, and Light Source Intensities and Images; 2. Experiments with Neutron Compound Refractive Lenses, Magnetic Lenses, and Microscopes; 3. Experiments with X-ray Compound Refractive Lenses and Microscopes; 4. Thermal Neutron Radiography, Coded Aperture, and Phase-Contrast Imaging; 5. Experiments in Fast Neutron Radiography; 6. A Brief History of Neutron Optics Before Compound Refractive Neutron Lenses.
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|a 7. Brief History and Overview of Diffractive and Reflective X-ray Optics and MicroscopyReferences; 2 Compound Refractive Lenses and Prisms; 1. The Compound Refractive Lens; 2. Numerical Aperture and Thin Lenses; 3. Biconcave Parabolic Lens: Path Length, Focal Length, and Absorption Aperture Radius; 4. Biconcave Spherical Lens: Path Length, Focal Length, and Absorption Aperture Radius; 5. Parabolic Aperture Radius in Spherical Biconcave CRLs; 6. Matrix Representation of X-ray and Neutron Optics with Paraxial Approximation; 7. Thin Lens Matrix and Ray Angle Deviation in a Thin Lens.
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|a 8. Average CRL Transmission for X-rays or Neutrons9. CRL Intensity Gain Including Attenuation; 10. CRL Transverse and Axial Magnification; 11. CRL Depth of Field and Depth of Focus; 12. Modulation Transfer Function for CRL Resolution Determination; 13. Calculation of CRL Modulation Transfer Function by Line Profile Measurements of Knife-Edge Images; 14. CRL Field of View; 15. Thick Lens CRLs; 16. CRL Surface Roughness and Lens Alignment; 17. Compound Refractive Prisms: X-ray and Neutron Deflection by a Single Prism; 18. Deflection of X-rays and Neutrons in a Compound Refractive Prism.
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|a X-ray microscopy.
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|a SCIENCE
|x Microscopes & Microscopy.
|2 bisacsh
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|a X-ray microscopy.
|2 fast
|0 (OCoLC)fst01181839
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|a Electronic books.
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|a Cremer, Jay Theodore,
|c Jr.
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|i Print version:
|a Cremer, Ted.
|t Advances in Imaging and Electron Physics : Part A.
|d Burlington : Elsevier Science, ©2012
|z 9780123944221
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|a Advances in imaging and electron physics ;
|v v. 172.
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|u https://www.sciencedirect.com/science/bookseries/10765670/172
|z Full Text via HEAL-Link
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