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Confocal Scanning Optical Microscopy and Related Imaging Systems

Corle, Timothy R.; Kino, Gordon S.
ISBN-10: 0124087507
ISBN-13: 9780124087507

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Description

Table of Contents

Author Bios

This book provides a comprehensive introduction to the field of scanning optical microscopy for scientists and engineers. These microscopes have been designed to overcome the problems associated with submicrometer imaging of complex three-dimensional structures. The book concentrates mainly on two of these instruments: the confocal scanning optical microscope (CSOM), and the optical interference microscope (OIM).

In these instruments a defocused image disappears rather than blurs as it does in a standard microscope. As a result, researchers can visualize submicrometer structures, determine their surface profiles, and observe a selected cross section of transparent materials withut cutting the sample into thin slices. A comprehensive discussion of the theory and design of the near-field scanning optical microscope (NSOM) is also given. The text also discusses the practical aspects of building a confocal scanning optical microscope or optical interference microscope and also considers the applications of these instruments to phase imaging, biological imaging, and semiconductor inspection and metrology. A comprehensive theoretical discussion of the depth and transverse resolution is included, with emphasis placed on the practical results of the theoretical calculations and their uses in understanding the operation of these microscopes.This book provides a comprehensive introduction to the field of scanning optical microscopy for scientists and engineers. The book concentrates mainly on two instruments: the Confocal Scanning Optical Microscope (CSOM), and the Optical Interference Microscope (OIM). A comprehensive discussion of the theory and design of the Near-Field Scanning Optical Microscope (NSOM) is also given. the text discusses the practical aspects of building a confocal scanning optical microscope or optical interference microscope, and the applications of these microscopes to phase imaging, biological imaging, and semiconductor inspection and metrology.A comprehensive theoretical discussion of the depth and transverse resolution is given with emphasis placed on the practical results of the theoretical calculations and how these can be used to help understand the operation of these microscopes.This book provides a comprehensive introduction to the field of scanning optical microscopy for scientists and engineers. The book concentrates mainly on two instruments: the Confocal Scanning Optical Microscope (CSOM), and the Optical Interference Microscope (OIM). A comprehensive discussion of the theory and design of the Near-Field Scanning Optical Microscope (NSOM) is also given. The text discusses the practical aspects of building a confocal scanning optical microscope or optical interference microscope, and the applications of these microscopes to phase imaging, biological imaging, and semiconductor inspection and metrology.A comprehensive theoretical discussion of the depth and transverse resolution is given with emphasis placed on the practical results of the theoretical calculations and how these can be used to help understand the operation of these microscopes. Key Features * Provides a comprehensive introduction to the field of scanning optical microscopy for scientists and engineers * Explains many practical applications of scanning optical and interference microscopy in such diverse fields as biology and semiconductor metrology * Discusses in theoretical terms the origin of the improved depth and transverse resolution of scanning optical and interference microscopes with emphasis on the practical results of the theoretical calculations * Considers the practical aspects of building a confocal scanning or interference microscope and explores some of the design tradeoffs made for microscopes used in various applications * Discusses the theory and design of near-field optical microscopes * Explains phase imaging in the scanning optical and interference microscopes

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Preface



Introduction



Confocal and Interferometric Microscopy



The Standard Optical Microscope



Principle of Operation



The Point Spread Function



Coherent and Incoherent Illumination



The Coherent Transfer Function, Line Spread Function, and Spatial Frequencies



The Optical Transfer Function



The Rayleigh and Sparrow Two-Point Definitions



Brightness of the Image



Imaging Techniques with the Standard Optical Microscope



The Confocal Microscope



Principle of Operation



Scanning



Depth Response



The Point Spread Function and Two-Point Resolution



History of the CSOM



Optical Interference Microscopes



Principle of Operation



Signal Processing Techniques



Depth and Transverse Resolution



Comparison of Scanning Optical Microscopes with Other Types of Scanning Microscopes


References



Instruments



Introduction



The Confocal Scanning Laser Microscope



The Illumination Source



The Objective Lens



The Scanning Stage



The Intermediate Optics



The Pinhole



The Detector and Electronics



Beam Scanning Techniques



Commercial Examples



Fiber-Optic Scanning Microscopes



Nipkow Disk Scanning Microscopes



One-Sided and Two-Sided Designs



The Nipkow Disk



Illumination of the Disk



The Tilted Disk and Optical Isolator



The Field Lens, Tube Lens, and Objective Lens



The Imaging Path



Commercial Examples



Slit Microscopes



Ophthalmologic Slit Microscopes



Bilateral Scanning Slit Microscopes



Hybrid Slit Microscopes



Confocal Transmission Microscopes



Alternative Imaging Configurations



Interference Microscopes



Interference CSOMs



The Michelson Interference Microscope



The Linnik Interference Microscope



The Mirau Interference Microscope



The Tolanski Interference Microscope



Near-Field Microscopy



The Near-Field Scanning Optical Microscope



Applications of the NSOM



The Solid Immersion Microscope



Conclusion


References



Depth and Transverse Resolution



Introduction



Depth Response of the Confocal Microscope with Infinitesimal Pinholes and Slits



Scalar Theory for a Plane Reflector



Scalar Theory for Depth Response of a Point Reflector



Scalar Theory for Fluorescent Reflectors



Scalar Theory for Confocal Slit Microscopes



The Effect of Sample and Lens Aberrations on the Depth Response



Depth Response of the Confocal Microscope with Finite-Sized Pinholes



Approximate Theory for Optimum Pinhole Size



Approximate Theory for the Range Resolution vs. Pinhole Size



Exact Theory for the Range Resolution vs. Pinhole Size



Transverse Response of the Confocal Microscope



Transverse Response for Infinitesimal Pinholes



Two-Point Resolution



Edge and Line Response



The Effect of Finite Pinhole Size on the Transverse Resolution



Depth and Transverse Resolution of the Interferometric Microscope



Scalar Theory for the Depth Response with a Plane Reflector



Transverse Resolution



The Effect of the Thin-Film Beamsplitter and Mirror Support of the MCM on Signal Levels, Range, and Transverse Resolution



The Near-Field Scanning Optical Microscope (NSOM)



Attenuation in a Tapered Rod or Fiber



The Fields outside the Pinhole



The Solid Immersion Microscope (SIM)



The Transverse and Longitudinal Magnifications of the SIL



The Depth Response of the SIM



The Transverse Response of the SIM



Conclusion


References



Phase Imaging



Introduction



Phase-Contrast Imaging in Conventional Microscopes



Phase-Contrast Imaging in the CSOM



Phase Imaging with an Interferometer



Electro-optic Phase Imaging



The ac Zernike Technique



Acousto-optic Phase Imaging



Differential Interference Contrast Imaging



The Basic Theory of Nomarski Imaging



Imaging Modes of a DIC Microscope



Polarization-Shifted DIC Imaging



Split Detector DIC Imaging



Differential Probe Beam DIC Imaging



Differential Imaging with an AO Modulator



Differential Imaging with an Optical Fiber CSOM



Phase Imaging with an Interference Microscope



The Integrating Bucket Technique



The Fourier Transform Technique



Conclusion


References



Applications



Introduction



Semiconductor Metrology



Microlithography Measurements



Precision, Linearity, and Accuracy in Semiconductor Metrology



Critical Dimension Measurements



Experimental Results



Polarization-Enhanced Imaging of Dense Arrays



Calibration



Overlay Misregistration Measurements



Film Thickness Measurements



CARIS and VAMFO



Film Thickness Measurements with the Mirau Interference Microscope



Biological Imaging



Brightfield and Phase Imaging



Fluorescence Imaging



Two-Wavelength and Two-Photon Fluorescence Imaging



Conclusion


References



Vector Field Theory for Depth and Transverse Resolution of a CSOM



The Depth Response



Transverse Response


References


Index

Edition:	1996
Publisher:	Elsevier Science & Technology Books
Binding:	Trade Cloth
Pages:	335
Size:	6.25" wide x 9.50" long x 0.75" tall
Weight:	1.43 lbs.
Language:	English

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