Wiley-VCH, Berlin Physical and Chemical Aspects of Organic Electronics Cover Experts from a variety of different fields describe their approaches to organic electronics, startin.. Product #: 978-3-527-40810-8 Regular price: $93.36 $93.36 In Stock

Physical and Chemical Aspects of Organic Electronics

From Fundamentals to Functioning Devices

Wöll, Christof (Editor)

Cover

1. Edition April 2009
LXIV, 634 Pages, Hardcover
476 Pictures (85 Colored Figures)
28 tables
Monograph

ISBN: 978-3-527-40810-8
Wiley-VCH, Berlin

Short Description

Experts from a variety of different fields describe their approaches to organic electronics, starting from the synthesis of appropriate materials and ending with the testing of real devices.

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Organic molecules are currently being investigated with regard to their application as active components in semiconductor devices. Whereas devices containing organic molecules for the generation of light - organic light emitting diodes (OLED) - have already reached the market (they e.g. display information on mobile phones), transistors where organic molecules are used to actively control currents and voltages are still in the development stage.
In this book the principle problems related to using organic materials as semiconductors and to construct functioning devices will be addressed.
A particular emphasis will be put on the difference between inorganic semiconductors such as Si, Ge and GaAs and organic semiconductors (OSC). The special properties of such soft matter require particular approaches for processing characterization and device implementation, which are quite different from the approach used for conventional semiconductors.

Part I Industrial Applications
1 Organic Transistors as a Basis for Printed Electronics
2 Printable Electronics: Flexibility for the Future
Part II Molecular Compounds
3 Fluorinated Phthalocyanines as Molecular Semiconductor Thin Films
4 Novel Organic Semiconductors and Processing Techniques for Organic Field-Effect Transistors
5 Assembly, Structure, and Performance of an Ultra-Thin Film Organic Field-Effect Transistor (OFET) Based
on Substituted Oligothiophenes
6 Organic Transistors Utilising Highly Soluble Swivel-Cruciform Oligothiophenes
Part III Structural and Morphological Aspects
7 Chemical Approaches to the Deposition of Metal Electrodes onto Self-Assembled Monolayers
8 Growth Morphologies and Charge Carrier Mobilities of Pentacene Organic Field Effect Transistors with
RF Sputtered Aluminium Oxide Gate Insulators on ITO Glass
9 In Situ X-Ray Scattering Studies of OFET Interfaces
10 X-Ray Structural and Crystallinity Studies of Low and High Molecular Weight Poly(3-hexylthiophene)
11 Molecular Beam Deposition and Characterisation of Thin Organic Films on Metals for Applications in Organic Electronics
12 Fundamental Interface Properties in OFETs: Bonding, Structure and Function of Molecular Adsorbate Layers on Solid Surfaces
13 Metal/Organic Interface Formation Studied In Situ by Resonant Raman Spectroscopy
14 Development of Single-Crystal OFETs Prepared on Well-Ordered Sapphire Substrates
Part IV Device Performance and Characterisation
15 Pentacene Devices: Molecular Structure, Charge Transport and Photo Response
16 Characteristics and Mechanisms of Hysteresis in Polymer Field-Effect Transistors
17 Ambipolar Charge Carrier Transport in Organic Semiconductor Blends
18 Gate Dielectrics and Surface Passivation Layers for Organic Field Effect Transistors
19 Influence of Metal Diffusion on the Electronic Properties of Pentacene and Diindenoperylene Thin Films
20 Potentiometry on Pentacene OFETs: Charge Carrier Mobilities and Injection Barriers in Bottom and Top Contact Configurations
21 Microscopic and Spectroscopic Characterisation of Interfaces and Dielectric Layers for OFET Devices
22 Scaling Limits and MHz Operation in Thiophene-Based Field- Effect Transistors
23 Aluminium Oxide Film as Gate Dielectric for Organic FETs: Anodisation and Characterisation
24 Electronic States at the Dielectric/Semiconductor Interface in Organic Field-Effect Transistors
25 Aspects of the Charge Carrier Transport in Highly-Ordered Crystals of Polyaromatic Molecules
Part V Novel Devices
26 Carbon Nanotube Transistors Chemical Functionalisation and Device Characterisation
27 Contact Effects in Cu(TCNQ) Memory Devices
28 Organic Field-Effect Transistors for Spin-Polarised Transport
Christof Wöll studied physics at the Georg-August University in Göttingen, Germany, and received his Ph.D. degree from the Max-Planck-Institute for Flow Research in 1987. From 1988 to 1989, he worked as a postdoctoral fellow at the IBM Division in San Jose, USA, researching in scanning tunnelling microscopy of clean and adsorbate covered metal surfaces. In 1992 followed his Habilitation in Physics from the University of Heidelberg, where he lectured in physical chemistry. From 1994 to 1996, Professor Wöll was a Heisenberg Fellow of the Deutsche Forschungsgemeinschaft at the Institute of Physical Chemistry, University of Heidelberg. He has published over 180 articles and is a member of the editorial boards of several journals.

C. Wöll, Ruhr-University Bochum, Germany