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Quantum Dots: Optics, Electron Transport and Future Applications
Hardback
Main Details
Title |
Quantum Dots: Optics, Electron Transport and Future Applications
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Authors and Contributors |
Edited by Alexander Tartakovskii
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Physical Properties |
Format:Hardback | Pages:378 | Dimensions(mm): Height 244,Width 170 |
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Category/Genre | Optics Nanotechnology |
ISBN/Barcode |
9781107012585
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Classifications | Dewey:620.5 |
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Audience | Professional & Vocational | |
Illustrations |
173 Line drawings, unspecified
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Publishing Details |
Publisher |
Cambridge University Press
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Imprint |
Cambridge University Press
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Publication Date |
19 July 2012 |
Publication Country |
United Kingdom
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Description
A comprehensive review of cutting-edge solid state research, focusing on its prominent example - quantum dot nanostructures - this book features a broad range of techniques for fabrication of these nano-structured semiconductors and control of their quantum properties. Written by leading researchers, the book considers advanced III-V and II-VI semiconductor quantum dots (QDs) realized by self-assembly, lithography and chemical synthesis; novel QD structures in nanowires and graphene; and transport and optical methods for control of single QDs. Significant attention is given to manipulation of single spins and control of their magnetic environment, and generation of quantum light emitted by single dots in dielectric cavities and coupled to plasmons in metallic structures. It is a valuable resource for graduate students and researchers new to this field.
Author Biography
Alexander Tartakovskii is a Reader in Experimental Semiconductor Physics, Department of Physics and Astronomy, University of Sheffield. He has been working in quantum dot research since 2001, recently with the focus on high-sensitivity nano-NMR in ultra-small nuclear spin ensembles in individual quantum dots.
Reviews'In this book, the reader will find a comprehensive review of QD design and applications written by 69 specialists in the field. Half of the book deals with fabrication methods, while the remaining half summarizes recent results on the control and characterization of QDs by optical techniques. A small part of the book is devoted to several examples for future applications in secure optical communications and linear optics quantum computing. This is a welcome addition to the literature and is suitable as a course material for graduate students. Beyond that, the specific topic of the title makes engaging reading.' Christian Brosseau, Optics and Photonics News
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