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Books in Optical materials

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31-40 of 138 results in All results

Thin Films for Emerging Applications

  • 1st Edition
  • Volume 16
  • October 22, 2013
  • John L. Vossen + 1 more
  • English
  • eBook
    9 7 8 - 1 - 4 8 3 2 - 8 8 9 1 - 8
Following in the long-standing tradition of excellence established by this serial, this volume provides a focused look at contemporary applications. High Tc superconducting thin films are discussed in terms of ion beam and sputtering deposition, vacuum evaporation, laser ablation, MOCVD, and other deposition processes in addition to their ultimate applications. Detailed treatment is also given to permanent magnet thin films, lateral diffusion and electromigration in metallic thin films, and fracture and cracking phenomena in thin films adhering to high-elongation substrates.

Optical Characterization of Real Surfaces and Films

  • 1st Edition
  • Volume 19
  • October 22, 2013
  • Maurice H. Francombe + 2 more
  • English
  • eBook
    9 7 8 - 1 - 4 8 3 2 - 8 8 9 3 - 2
This new volume of the highly respected Physics of Thin Films Serial discusses inhomogeneity in real films and surfaces. The volume, guest-edited by K. Vedam, follows the growth of thin films both from the surface of the substrate, and from the atomic level, layer by layer. The text features coverage of Real-Time Spectroscopic Ellipsometry (RTSE) and Reflectance Anisotropy (RA), two major breakthrough optical techniques used to characterize real time and insitu films and surfaces. In six insightful chapters, the contributors assess the impact of these techniques, their strengths and limitations, and their potential for further development.

Compound Semiconductor Device Physics

  • 1st Edition
  • October 22, 2013
  • Sandip Tiwari
  • English
  • eBook
    9 7 8 - 1 - 4 8 3 2 - 8 9 2 9 - 8
This book provides one of the most rigorous treatments of compound semiconductor device physics yet published. A complete understanding of modern devices requires a working knowledge of low-dimensional physics, the use of statistical methods, and the use of one-, two-, and three-dimensional analytical and numerical analysis techniques. With its systematic and detailed**discussion of these topics, this book is ideal for both the researcher and the student. Although the emphasis of this text is on compound semiconductor devices, many of the principles discussed will also be useful to those interested in silicon devices. Each chapter ends with exercises that have been designed to reinforce concepts, to complement arguments or derivations, and to emphasize the nature of approximations by critically evaluating realistic conditions.

Organic Light-Emitting Diodes (OLEDs)

  • 1st Edition
  • August 31, 2013
  • Alastair Buckley
  • English
  • eBook
    9 7 8 - 0 - 8 5 7 0 9 - 8 9 4 - 8
Organic light-emitting diodes (OLEDs) are opening up exciting new applications in the area of lighting and displays. OLEDs are self emissive and by careful materials and device design can generate colours across the visible spectrum. Together with simple monolithic fabrication on a range of different substrates, these diverse material properties give OLEDs key advantages over existing display and lighting technology. This important book summarises key research on materials, engineering and the range of applications of these versatile materials.Part one covers materials for OLEDs. Chapters review conjugated polymers, transparent conducting thin films, iridium complexes and phosphorescent materials. Part two discusses the operation and engineering of OLED devices. Chapters discuss topics such as highly efficient pin-type OLEDs, amorphous organic semiconductors, nanostructuring techniques, light extraction, colour tuning, printing techniques, fluorenone defects and disruptive characteristics as well as durability issues. Part three explores the applications of OLEDs in displays and solid-state lighting. Applications discussed include displays, microdisplays and transparent OLEDs, sensors and large-area OLED lighting panels.Organic light-emitting diodes (OLEDs) is a standard reference for engineers working in lighting, display technology and the consumer electronics sectors, as well as those researching OLEDs.

Fine Line Lithography

  • 1st Edition
  • Volume 1
  • December 2, 2012
  • R Newman
  • English
  • eBook
    9 7 8 - 0 - 4 4 4 - 6 0 1 2 8 - 5
Materials Processing - Theory and Practices, Volume 1: Fine Line Lithography reviews technical information as well as the theory and practices of materials processing. It looks at very large scale integration (VLSI) technology, with emphasis on the creation of fine line patterned structures that make up the devices and interconnects of complex functional circuits. It also describes a variety of other technologies that provide finer patterns, from modified versions of optical methods to electron-optic systems, non-plus-ultra of X-ray techniques, and dry processing that uses the chemical or kinetic energies of gas molecules or ions. Organized into five chapters, this volume begins with an overview of the fundamentals of electron and X-ray lithography, with a focus on resists and the way they function, and how they are used in microfabrication. It then discusses electron scattering and its effects on resist exposure and development, electron-beam lithography equipment, X-ray lithography, and optical methods for fine line lithography. It systematically introduces the reader to electron-beam projection techniques, dry processing methods, and application of electron-beam technology to large-scale integrated circuits. Other chapters focus on contact and proximity printing, projection printing, deep-UV lithography, and shadow printing with electrons and ions. The book describes reactive plasma etching and ion beam etching before concluding with a look at factors affecting the performance of the scanning-probe type of systems. This book is a valuable resource for materials engineers and processing engineers, as well as those in the academics and industry.

Computer Design of Diffractive Optics

  • 1st Edition
  • November 19, 2012
  • V A Soifer
  • English
  • Hardback
    9 7 8 - 1 - 8 4 5 6 9 - 6 3 5 - 1
  • eBook
    9 7 8 - 0 - 8 5 7 0 9 - 3 7 4 - 5
Diffractive optics involves the manipulation of light using diffractive optical elements (DOEs). DOEs are being widely applied in such areas as telecommunications, electronics, laser technologies and biomedical engineering. Computer design of diffractive optics provides an authoritative guide to the principles and applications of computer-designed diffractive optics.The theoretical aspects underpinning diffractive optics are initially explored, including the main equations in diffraction theory and diffractive optical transformations. Application of electromagnetic field theory for calculating diffractive gratings and related methods in micro-optics are discussed, as is analysis of transverse modes of laser radiation and the formation of self-replicating multimode laser beams. Key applications of DOEs reviewed include geometrical optics approximation, scalar approximation and optical manipulation of micro objects, with additional consideration of multi-order DOEs and synthesis of DOEs on polycrystalline diamond films.With its distinguished editor and respected team of expert contributors, Computer design of diffractive optics is a comprehensive reference tool for professionals and academics working in the field of optical engineering and photonics.

Optical Phase Conjugation

  • 1st Edition
  • November 12, 2012
  • Robert A. Fisher
  • English
  • eBook
    9 7 8 - 0 - 3 2 3 - 1 4 0 1 1 - 9
This book appears at a time of intense activity in optical phase conjugation. We chose not to await the maturation of the field, but instead to provide this material in time to be useful in its development. We have tried very hard to elucidate and interrelate the various nonlinear phenomena which can be used for optical phase conjugation.

Laser Growth and Processing of Photonic Devices

  • 1st Edition
  • July 10, 2012
  • Nikolaos A Vainos
  • English
  • Hardback
    9 7 8 - 1 - 8 4 5 6 9 - 9 3 6 - 9
  • eBook
    9 7 8 - 0 - 8 5 7 0 9 - 6 2 2 - 7
The use of lasers in the processing of electronic and photonic material is becoming increasingly widespread, with technological advances reducing costs and increasing both the quality and range of novel devices which can be produced. Laser growth and processing of photonic devices is the first book to review this increasingly important field.Part one investigates laser-induced growth of materials and surface structures, with pulsed laser deposition techniques, the formation of nanocones and the fabrication of periodic photonic microstructures explored in detail. Laser-induced three-dimensional micro- and nano-structuring are the focus of part two. Exploration of multiphoton lithography, processing and fabrication is followed by consideration of laser-based micro- and nano-fabrication, laser-induced soft matter organization and microstructuring, and laser-assisted polymer joining methods. The book concludes in part three with an investigation into laser fabrication and manipulation of photonic structures and devices. Laser seeding and thermal processing of glass with nanoscale resolution, laser-induced refractive index manipulation, and the thermal writing of photonic devices in glass and polymers are all considered.With its distinguished editor and international team of expert contributors, Laser growth and processing of photonic devices is an essential tool for all materials scientists, engineers and researchers in the microelectronics industry.

Advances in Imaging and Electron Physics

  • 1st Edition
  • Volume 142
  • July 29, 2011
  • Peter W. Hawkes
  • English
  • eBook
    9 7 8 - 0 - 0 8 - 0 4 6 2 8 3 - 7
Advances in Imaging and Electron Physics merges two long-running serials-Advances in Electronics and Electron Physics and Advances in Optical and Electron Microscopy. This series features extended articles on the physics of electron devices (especially semiconductor devices), particle optics at high and low energies, microlithography, image science and digital image processing, electromagnetic wave propagation, electron microscopy, and the computing methods used in all these domains.

Lens Design Fundamentals

  • 2nd Edition
  • November 20, 2009
  • Rudolf Kingslake + 1 more
  • English
  • Hardback
    9 7 8 - 0 - 1 2 - 3 7 4 3 0 1 - 5
  • eBook
    9 7 8 - 0 - 0 8 - 0 9 2 1 5 6 - 3
Thoroughly revised and expanded to reflect the substantial changes in the field since its publication in 1978 Strong emphasis on how to effectively use software design packages, indispensable to today’s lens designer Many new lens design problems and examples – ranging from simple lenses to complex zoom lenses and mirror systems – give insight for both the newcomer and specialist in the field Rudolf Kingslake is regarded as the American father of lens design; his book, not revised since its publication in 1978, is viewed as a classic in the field. Naturally, the area has developed considerably since the book was published, the most obvious changes being the availability of powerful lens design software packages, theoretical advances, and new surface fabrication technologies. This book provides the skills and knowledge to move into the exciting world of contemporary lens design and develop practical lenses needed for the great variety of 21st-century applications. Continuing to focus on fundamental methods and procedures of lens design, this revision by R. Barry Johnson of a classic modernizes symbology and nomenclature, improves conceptual clarity, broadens the study of aberrations, enhances discussion of multi-mirror systems, adds tilted and decentered systems with eccentric pupils, explores use of aberrations in the optimization process, enlarges field flattener concepts, expands discussion of image analysis, includes many new exemplary examples to illustrate concepts, and much more. Optical engineers working in lens design will find this book an invaluable guide to lens design in traditional and emerging areas of application; it is also suited to advanced undergraduate or graduate course in lens design principles and as a self-learning tutorial and reference for the practitioner. Rudolf Kingslake (1903-2003) was a founding faculty member of the Institute of Optics at The University of Rochester (1929) and remained teaching until 1983. Concurrently, in 1937 he became head of the lens design department at Eastman Kodak until his retirement in 1969. Dr. Kingslake published numerous papers, books, and was awarded many patents. He was a Fellow of SPIE and OSA, and an OSA President (1947-48). He was awarded the Progress Medal from SMPTE (1978), the Frederic Ives Medal (1973), and the Gold Medal of SPIE (1980). R. Barry Johnson has been involved for over 40 years in lens design, optical systems design, and electro-optical systems engineering. He has been a faculty member at three academic institutions engaged in optics education and research, co-founder of the Center for Applied Optics at the University of Alabama in Huntsville, employed by a number of companies, and provided consulting services. Dr. Johnson is an SPIE Fellow and Life Member, OSA Fellow, and an SPIE President (1987). He published numerous papers and has been awarded many patents. Dr. Johnson was founder and Chairman of the SPIE Lens Design Working Group (1988-2002), is an active Program Committee member of the International Optical Design Conference, and perennial co-chair of the annual SPIE Current Developments in Lens Design and Optical Engineering Conference.