Organic Nanostructures for Next Generation Devices (eBook, PDF)
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Organic Nanostructures for Next Generation Devices (eBook, PDF)
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Produktdetails
- Verlag: Springer Berlin
- Erscheinungstermin: 29. Dezember 2007
- Englisch
- ISBN-13: 9783540719236
- Artikelnr.: 37369020
Here is the first comprehensive overview of the fabrication, fundamental properties, and applications of a new class of nanoscaled organic materials that holds huge promise for optical and electrical applications. By using controlled self-assembled growth on single crystal surfaces, fiber-like structures are fabricated with macroscopic lengths up to millimeter size, mesoscopic widths of mere hundreds of nanometers, and nanoscopic heights of tens of nanometers. The extraordinary beauty of these new structures is that they are quasi single crystalline, providing superior optical and electronic properties that can be freely tailored via functionalization of their organic building blocks. Altogether, the book offers a unique integration of organic materials science basics, nanostructured organic materials fabrication, and device applications.
Fundamentals of Organic Film Growth and Characterisation.- Optical Characterization Methods for Ultrathin Nanoaggregates.- Growth.- Growth of Oriented Organic Nanoaggregates via Molecular Beam Deposition.- Tailored Organic Nanoaggregates Generated by Self-Assembly of Designed Functionalised p-Quaterphenylenes on Muscovite Mica Substrates.- Hot-Wall Epitaxial Growth of Films of Conjugated Molecules.- Crystallography of Ultrathin Organic Films and Nanoaggregates.- Growth and Electronic Structure of Homo- and Hetero-epitaxial Organic Nanostructures.- Mechanisms Governing the Growth of Organic Oligophenylene “Needles” on Au Substrates.- Optics.- Nanooptics Using Organic Nanofibers.- Optical Gain and Random Lasing in Self-Assembled Organic Nanofibers.- Applications.- Fabrication and Characterization of Self-Organized Nanostructured Organic Thin Films and Devices.- Device-Oriented Studies on Electrical, Optical, and Mechanical Properties of Individual Organic Nanofibers.- Device Treatment of Organic Nanofibers: Embedding, Detaching, and Cutting.
Fundamentals of Organic Film Growth and Characterisation.- Optical Characterization Methods for Ultrathin Nanoaggregates.- Growth.- Growth of Oriented Organic Nanoaggregates via Molecular Beam Deposition.- Tailored Organic Nanoaggregates Generated by Self-Assembly of Designed Functionalised p-Quaterphenylenes on Muscovite Mica Substrates.- Hot-Wall Epitaxial Growth of Films of Conjugated Molecules.- Crystallography of Ultrathin Organic Films and Nanoaggregates.- Growth and Electronic Structure of Homo- and Hetero-epitaxial Organic Nanostructures.- Mechanisms Governing the Growth of Organic Oligophenylene "Needles" on Au Substrates.- Optics.- Nanooptics Using Organic Nanofibers.- Optical Gain and Random Lasing in Self-Assembled Organic Nanofibers.- Applications.- Fabrication and Characterization of Self-Organized Nanostructured Organic Thin Films and Devices.- Device-Oriented Studies on Electrical, Optical, and Mechanical Properties of Individual Organic Nanofibers.- Device Treatment of Organic Nanofibers: Embedding, Detaching, and Cutting.
Fundamentals of Organic Film Growth and Characterisation.- Optical Characterization Methods for Ultrathin Nanoaggregates.- Growth.- Growth of Oriented Organic Nanoaggregates via Molecular Beam Deposition.- Tailored Organic Nanoaggregates Generated by Self-Assembly of Designed Functionalised p-Quaterphenylenes on Muscovite Mica Substrates.- Hot-Wall Epitaxial Growth of Films of Conjugated Molecules.- Crystallography of Ultrathin Organic Films and Nanoaggregates.- Growth and Electronic Structure of Homo- and Hetero-epitaxial Organic Nanostructures.- Mechanisms Governing the Growth of Organic Oligophenylene “Needles” on Au Substrates.- Optics.- Nanooptics Using Organic Nanofibers.- Optical Gain and Random Lasing in Self-Assembled Organic Nanofibers.- Applications.- Fabrication and Characterization of Self-Organized Nanostructured Organic Thin Films and Devices.- Device-Oriented Studies on Electrical, Optical, and Mechanical Properties of Individual Organic Nanofibers.- Device Treatment of Organic Nanofibers: Embedding, Detaching, and Cutting.
Fundamentals of Organic Film Growth and Characterisation.- Optical Characterization Methods for Ultrathin Nanoaggregates.- Growth.- Growth of Oriented Organic Nanoaggregates via Molecular Beam Deposition.- Tailored Organic Nanoaggregates Generated by Self-Assembly of Designed Functionalised p-Quaterphenylenes on Muscovite Mica Substrates.- Hot-Wall Epitaxial Growth of Films of Conjugated Molecules.- Crystallography of Ultrathin Organic Films and Nanoaggregates.- Growth and Electronic Structure of Homo- and Hetero-epitaxial Organic Nanostructures.- Mechanisms Governing the Growth of Organic Oligophenylene "Needles" on Au Substrates.- Optics.- Nanooptics Using Organic Nanofibers.- Optical Gain and Random Lasing in Self-Assembled Organic Nanofibers.- Applications.- Fabrication and Characterization of Self-Organized Nanostructured Organic Thin Films and Devices.- Device-Oriented Studies on Electrical, Optical, and Mechanical Properties of Individual Organic Nanofibers.- Device Treatment of Organic Nanofibers: Embedding, Detaching, and Cutting.