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Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
|---|---|---|---|---|---|
Searching... | 30000010345579 | QD381.9.O66 O68 2015 | Open Access Book | Book | Searching... |
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Summary
Summary
Optical Properties of Functional Polymers and Nano Engineering Applications provides a basic introduction to the optical properties of polymers, as well as a systematic overview of the latest developments in their nano engineering applications. Covering an increasingly important class of materials relevant not only in academic research but also in industry, this comprehensive text:
Considers the advantages of the liquid gradient refractive index (L-GRIN) lenses over the conventional solid lenses Explores the electrochemistry of photorefractive polymers, the molecular structure of commonly used polymers, and various 3D holographic displays Discusses gene detection using the optical properties of conjugated polymers Highlights the physics of fluorescence in photoluminescent polymers, and energy and electron transfer mechanisms Introduces conventional polymer ion sensors based on the optical sensors of conjugated polymers prepared by click chemistry reactions Explains colorimetric visual detection of ions by donor-acceptor chromophores Describes optical sensors based on fluorescent polymers and for the detection of explosives and metal ion analytes Addresses holographic polymer-dispersed liquid crystal technology, its optical setups, and its applications in organic lasers Presents cutting-edge research on electrochromic devices, along with new concepts, prototypes, commercial products, and future prospects Demonstrates new techniques for creating nanoscale morphologies through self-assembly, which affect the optical properties of the functional polymersOptical Properties of Functional Polymers and Nano Engineering Applications emphasizes the importance of nano engineering in improving the fundamental optical properties of the functional polymers, elaborating on high-level research while thoroughly explaining the underlying principles.
Author Notes
Dr. Vaibhav Jain currently works in private industry and is a subject matter expert in materials science and engineering. Before that, he was a materials engineer in the Optical Sciences Division of the Naval Research Lab from 2011 to 2013. From 2009 to 2011, he worked in the same division as a National Research Council postdoctoral researcher. Dr. Jain received his Ph.D from Virginia Tech in macromolecular science and engineering in 2009, and his undergraduate degree in polymer science and chemical technology from Delhi College of Engineering, New Delhi, India. He has coauthored 35 publications and more than 50 conference presentations.
Akshay Kokil is a materials scientist with diverse academic and industrial research experience. Dr. Kokil received his undergraduate education in polymer engineering at University of Pune, India, and earned his Ph.D in macromolecular science and engineering from Case Western Reserve University, Cleveland, Ohio, USA. He has authored more than 45 publications, and presented his research at multiple international research conferences. Several of his papers have been featured on journal covers and highlighted in research sections of magazines and websites. He is also the author of the book Conjugated Polymer Networks: Synthesis and Properties .
Table of Contents
| Preface | p. vii |
| Editors | p. ix |
| Contributors | p. xi |
| 1 Optical and Optoelectronic Properties of Polymers and Their Nanoengineering Applications | p. 1 |
| 2 Liquid Gradient Refractive Index Lenses | p. 3 |
| 3 Photorefractive Polymers for 3D Display Application | p. 27 |
| 4 Optical Gene Detection Using Conjugated Polymers | p. 61 |
| 5 Polymer Ion Sensors Based on Intramolecular Charge-Transfer Interactions | p. 87 |
| 6 Detection of Explosives and Metal Ions Using Fluorescent Polymers and Their Nanostructures | p. 105 |
| 7 Holographic Polymer-Dispersed Liquid Crystals: From Materials and Morphologies to Applications | p. 145 |
| 8 Organic and Organic-Inorganic Hybrid Electrochromic Materials and Devices | p. 187 |
| 9 Polymer Nanostructures through Packing of Spheres | p. 227 |
| Index | p. 263 |
