Organic electronics : emerging concepts and technologies /
An overview of the tremendous potential of organic electronics, concentrating on those emerging topics and technologies that will form the focus of research over the next five to ten years. The young and energetic team of editors with an excellent research track record has brought together internati...
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| Format: | eBook |
| Language: | English |
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Weinheim, Germany :
Wiley-VCH,
©2013.
Weinheim : 2013. |
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| Online Access: | Connect to the full text of this electronic book |
Table of Contents:
- Machine generated contents note: 1.1.Introduction / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.Nanoparticles Based on Fluorene Polymers / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.1.Optoelectronic Applications / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.1.1.Characterization of Nanoparticles / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.1.2.Nanoparticle Film Fabrication and Characterization / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.1.3.OLEDs / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.1.4.Solar Cell Applications / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.2.Imaging and Sensing Applications / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.2.1.Characterization of Nanoparticles / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.2.2.Biosensing / Albertus P.H.J. Schenning / Irén Fischer
- 1.2.2.3.Bioimaging / Albertus P.H.J. Schenning / Irén Fischer
- Note continued: 1.3.Nanoparticles Based on Fluorene Oligomer / Albertus P.H.J. Schenning / Irén Fischer
- 1.3.1.Characterization / Albertus P.H.J. Schenning / Irén Fischer
- 1.3.2.Nanoparticles for Sensing and Imaging / Albertus P.H.J. Schenning / Irén Fischer
- 1.4.Conclusions and Perspectives / Albertus P.H.J. Schenning / Irén Fischer
- References / Albertus P.H.J. Schenning / Irén Fischer
- 2.1.Introduction / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.2.Conducting Polymers for Biological Applications / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.2.1.Unique Benefits of Conducting Polymers / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.2.2.Biocompatibility of Conducting Polymers / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.2.3.Electrochemical Properties and Tools / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- Note continued: 2.3.Conducting Polymers to Control Cells / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.1.Establishing Conducting Polymers as Cell Culture Environments / Jonathan Rivnay / Leslie H. Jimison / Róisin M. Owens
- 2.3.2.Optimizing Conducting Polymers for Cell Culture / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.3.Controlling Cell Adhesion via Redox State / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.3.1.Redox Switches / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.3.2.Redox Gradients / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.3.3.Protein Characterization as a Function of Redox State / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.4.Direct Patterning of Proteins to Control Cell Adhesion / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.5.Controlling Cell Growth and Development / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- Note continued: 2.3.5.1.Electrical Stimulation to Promote Neurite Formation and Extension / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.5.2.Electrical Stimulation to Promote Muscle Cell Proliferation and Differentiation / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.5.3.Alignment Control via Topographical Cues / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.5.4.Incorporation of Biomolecules to Control Differentiation / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.6.Organic Electronic Ion Pumps / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.7.On-Demand Cell Release / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.8.Conducting Polymer Actuators / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.3.9.Optoelectronic Control of Cell Behavior / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- Note continued: 2.4.Conducting Polymers to Monitor Cells / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.4.1.Conducting Polymers to Monitor Neuronal Function / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.4.1.1.Conducting Polymer Electrodes / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.4.1.2.Transistors / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.4.2.Conducting Polymers to Monitor Behavior of Nonelectrically Active Cells / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 2.5.Conclusions / Róisin M. Owens / Jonathan Rivnay / Leslie H. Jimison
- References / Leslie H. Jimison / Róisin M. Owens / Jonathan Rivnay
- 3.1.Introduction / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.Regenerative Medicine and Biomedical Devices / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.1.Scaffolds, Signaling Interfaces, and Surfaces for Novel Biomedical Applications / Peter Kjäll / Salvador Gomez-Carretero
- Note continued: 3.2.1.1.Scaffolds and Surface Modulation / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.1.2.Biomolecule Presenting Surfaces / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.1.3.Degradable Surfaces for Biomedical Applications / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.1.4.Controlled Substance Release / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.2.Prosthetics and Medical Devices / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.2.1.Organic Bioelectronics as Actuators / Peter Kjäll / Salvador Gomez-Carretero
- 3.2.2.2.Neuroprosthetics / Peter Kjäll / Salvador Gomez-Carretero
- 3.3.Organic Electronics in Biomolecular Sensing and Diagnostic Applications / Peter Kjäll / Salvador Gomez-Carretero
- 3.3.1.Organic Electronics as Biomolecule Sensors: A Technological Overview / Peter Kjäll / Salvador Gomez-Carretero
- 3.3.2.Small-Molecule and Biological Metabolite Sensing / Peter Kjäll / Salvador Gomez-Carretero
- Note continued: 3.3.3.Immunosensors / Peter Kjäll / Salvador Gomez-Carretero
- 3.3.4.DNA Sensing / Peter Kjäll / Salvador Gomez-Carretero
- 3.3.5.Medical Diagnosis and the Electronic Nose / Peter Kjäll / Salvador Gomez-Carretero
- 3.4.Concluding Remarks / Peter Kjäll / Salvador Gomez-Carretero
- References / Peter Kjäll / Salvador Gomez-Carretero
- 4.1.Introduction and Background / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- 4.2.Physical and Optical Properties of Melanin and the Transport Physics of Disordered Semiconductors / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- 4.3.The Hydration Dependence of Melanin Conductivity / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- 4.4.Muon Spin Relaxation Spectroscopy and Electron Paramagnetic Resonance / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- 4.5.Transport Model for Electrical Conduction and Photoconduction in Melanin / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- Note continued: 4.6.Bioelectronics, Hybrid Devices, and Future Perspectives / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- References / Paul Meredith / Albertus B. Mostert / Kristen Tandy
- 5.1.Introduction: The Nature-Inspired / Julia Wünsche / Alessandro Pezzella
- 5.2.Natural Melanins / Alessandro Pezzella / Julia Wünsche
- 5.2.1.Overview / Julia Wünsche / Alessandro Pezzella
- 5.2.2.Distribution and Isolation of Natural Eumelanin / Julia Wünsche / Alessandro Pezzella
- 5.2.3.Melanogenesis: From Understanding the In Vivo Path to In Vitro Pigment Preparation / Julia Wünsche / Alessandro Pezzella
- 5.3.Synthetic Melanins / Julia Wünsche / Alessandro Pezzella
- 5.3.1.Overview / Julia Wünsche / Alessandro Pezzella
- 5.3.2.Oxidative Polymerization of 5,6-Dihydroxyindole(s) / Julia Wünsche / Alessandro Pezzella
- 5.4.Chemical-Physical Properties and Structure-Property Correlation / Julia Wünsche / Alessandro Pezzella
- Note continued: 5.4.1.Stability against Acids and Bases / Julia Wünsche / Alessandro Pezzella
- 5.4.2.Molecular Weight / Julia Wünsche / Alessandro Pezzella
- 5.4.3.Hydration, Aggregation, and Supramolecular Organization / Julia Wünsche / Alessandro Pezzella
- 5.4.4.Light Absorption and Scattering / Julia Wünsche / Alessandro Pezzella
- 5.4.5.Metal Chelation / Julia Wünsche / Alessandro Pezzella
- 5.4.6.Redox State / Julia Wünsche / Alessandro Pezzella
- 5.4.7.Autoxidation / Julia Wünsche / Alessandro Pezzella
- 5.4.8.Bleaching / Julia Wünsche / Alessandro Pezzella
- 5.4.9.NMR Spectroscopy / Julia Wünsche / Alessandro Pezzella
- 5.4.10.EPR Spectroscopy / Julia Wünsche / Alessandro Pezzella
- 5.5.Thin Film Fabrication / Julia Wünsche / Alessandro Pezzella
- 5.6.Melanin Hybrid Materials / Julia Wünsche / Alessandro Pezzella
- 5.7.Conclusions / Julia Wünsche / Alessandro Pezzella
- References / Alessandro Pezzella / Julia Wünsche
- Note continued: 6.1. Introduction / Thomas W. Phillips / John C. de Mello
- 6.1.1. Indium Tin Oxide / Thomas W. Phillips / John C. de Mello
- 6.1.2. Optoelectronic Characteristics / Thomas W. Phillips / John C. de Mello
- 6.1.2.1. The Influence of Sheet Resistance / Thomas W. Phillips / John C. de Mello
- 6.1.2.2. Optical Transparency / Thomas W. Phillips / John C. de Mello
- 6.1.2.3. Transmittance Versus Sheet Resistance Trade-off Characteristics / Thomas W. Phillips / John C. de Mello
- 6.1.2.4. Work Function / Thomas W. Phillips / John C. de Mello
- 6.2. Emergent Electrode Materials / Thomas W. Phillips / John C. de Mello
- 6.2.1. Graphene / John C. de Mello / Thomas W. Phillips
- 6.2.1.1. Fabrication / John C. de Mello / Thomas W. Phillips
- 6.2.1.2. Outlook / John C. de Mello / Thomas W. Phillips
- 6.2.2. Carbon Nanotubes / John C. de Mello / Thomas W. Phillips
- 6.2.2.1. Structure / John C. de Mello / Thomas W. Phillips
- Note continued: 6.2.2.2.Networks / John C. de Mello / Thomas W. Phillips
- 6.2.2.3. Film Fabrication / John C. de Mello / Thomas W. Phillips
- 6.2.2.4. Improving Performance / John C. de Mello / Thomas W. Phillips
- 6.2.3. Metal Nanowires / John C. de Mello / Thomas W. Phillips
- 6.2.3.1. Silver Nanowires / John C. de Mello / Thomas W. Phillips
- 6.2.3.2. Alternative Metal Nanowires / John C. de Mello / Thomas W. Phillips
- 6.3. Conclusions / John C. de Mello / Thomas W. Phillips
- References / John C. de Mello / Thomas W. Phillips
- 7.1. Polymer Light-Emitting Electrochemical Cells / Janelle Leger / Sam Toshner
- 7.2. Ionic Carriers / Janelle Leger / Sam Toshner
- 7.3. Fixed Ionic Carriers / Janelle Leger / Sam Toshner
- 7.4. Fixed Junction LEC-Based Photovoltaic Devices / Janelle Leger / Sam Toshner
- 7.5. Conclusions / Janelle Leger / Sam Toshner
- References / Janelle Leger / Sam Toshner
- 8.1. Introduction / Jana Zaumseil
- Note continued: 8.2. Working Principle / Jana Zaumseil
- 8.2.1. Unipolar LEFETs / Jana Zaumseil
- 8.2.2. Ambipolar LEFETs / Jana Zaumseil
- 8.3. Recent Trends and Developments / Jana Zaumseil
- 8.3.1. Heterojunction Light-Emitting FETs / Jana Zaumseil
- 8.3.2. Single-Crystal Light-Emitting FETs / Jana Zaumseil
- 8.3.3. Carbon Nanotube Light-Emitting FETs / Jana Zaumseil
- 8.4. Conclusions / Jana Zaumseil
- References / Jana Zaumseil
- 9.1. Introduction / Fabio Cicoira / Sareh Bayatpour / Jonathan Sayago / Clara Santato
- 9.2. Electrolyte-Gated Organic Transistors / Jonathan Sayago / Clara Santato / Fabio Cicoira / Sareh Bayatpour
- 9.3. Electrolytes Employed in Electrolyte-Gated Organic Transistors / Jonathan Sayago / Clara Santato / Fabio Cicoira / Sareh Bayatpour
- 9.4. Preliminary Results and Challenges in Electrolyte-Gated Organic Light-Emitting Transistors / Jonathan Sayago / Clara Santato / Fabio Cicoira / Sareh Bayatpour
- Note continued: 9.5. Relevant Questions and Perspectives in the Field of EG-OLETs / Jonathan Sayago / Clara Santato / Fabio Cicoira / Sareh Bayatpour
- References / Jonathan Sayago / Clara Santato / Fabio Cicoira / Sareh Bayatpour
- 10.1. Introduction / Oksana Ostroverkhova
- 10.2. Overview of Materials / Oksana Ostroverkhova
- 10.2.1. Benzothiophene, Anthradithiophene, and Longer Heteroacene Derivatives / Oksana Ostroverkhova
- 10.2.2. Pentacene and Hexacene Derivatives / Oksana Ostroverkhova
- 10.2.3. Indenofluorene Derivatives / Oksana Ostroverkhova
- 10.3. Optical and Photoluminescent Properties of Molecules in Solutions and in Host Matrices / Oksana Ostroverkhova
- 10.4. Aggregation and Its Effect on Optoelectronic Properties / Oksana Ostroverkhova
- 10.4.1.J-Versus H-Aggregate Formation / Oksana Ostroverkhova
- 10.4.2. Example of Aggregation: Disordered H-Aggregates in ADT-TES-F Films / Oksana Ostroverkhova
- Note continued: 10.4.2.1. Aggregate Formation: Optical and Photoluminescent Properties / Oksana Ostroverkhova
- 10.4.2.2. Aggregate Formation: Photoconductive Properties / Oksana Ostroverkhova
- 10.4.2.3. ADT-TES-F Aggregates: Identification and Properties / Oksana Ostroverkhova
- 10.4.3. Effects of Molecular Packing on Spectra / Oksana Ostroverkhova
- 10.4.3.1. Molecular Structure and Solid-State Packing / Oksana Ostroverkhova
- 10.4.3.2. Film Morphology and Spectra / Oksana Ostroverkhova
- 10.5.(Photo)Conductive Properties of Pristine Materials / Oksana Ostroverkhova
- 10.5.1. Ultrafast Photophysics and Charge Transport on Picosecond Timescales / Oksana Ostroverkhova
- 10.5.2. Charge Transport on Nanosecond and Longer Timescales / Oksana Ostroverkhova
- 10.5.3. Dark Current and cw Photocurrent / Oksana Ostroverkhova
- 10.6. Donor-Acceptor Composites / Oksana Ostroverkhova
- 10.6.1. Donor-Acceptor Interactions: FRET versus Exciplex Formation / Oksana Ostroverkhova
- Note continued: 10.6.2. Donor-Acceptor Interactions Depending on the Donor-Acceptor LUMO Energies Offset, Donor and Acceptor Separation, and Film Morphology / Oksana Ostroverkhova
- 10.6.2.1. Effects on the Photoluminescence / Oksana Ostroverkhova
- 10.6.2.2. Effects on the Photocurrent / Oksana Ostroverkhova
- 10.7. Summary and Outlook / Oksana Ostroverkhova
- References / Oksana Ostroverkhova
- 11.1. Introduction / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.2. Device Architectures and Operating Principles / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.2.1. Device Architectures / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.2.1.1. Active Layer / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.2.1.2. Contacts / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- Note continued: 11.2.2. Energetics of Charge Generation in OPV Devices / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.3. Bandgap Engineering: Low-Bandgap Polymers / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.4. Molecular Acceptor Materials for OPV / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.4.1. Morphology / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.4.2. Electron Affinity / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.4.3. Stabilization of Reduced Acceptor / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.4.4.Complementary Light Absorption / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- 11.5. Summary / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- References / Andrew Ferguson / Nikos Kopidakis / Dana Olson / Wade Braunecker
- Note continued: 12.1. Introduction / Yoshihiro Iwasa / Taishi Takenobu
- 12.2. Single-Crystal Growth / Yoshihiro Iwasa / Taishi Takenobu
- 12.3. MISFET / Yoshihiro Iwasa / Taishi Takenobu
- 12.4. Schottky Diode and MESFET / Yoshihiro Iwasa / Taishi Takenobu
- 12.5. Ambipolar Transistor / Yoshihiro Iwasa / Taishi Takenobu
- 12.6. Light-Emitting Ambipolar Transistor / Yoshihiro Iwasa / Taishi Takenobu
- 12.7. Electric Double-Layer Transistor / Yoshihiro Iwasa / Taishi Takenobu
- 12.8. Conclusion / Yoshihiro Iwasa / Taishi Takenobu
- References / Yoshihiro Iwasa / Taishi Takenobu
- 13.1. Introduction / Oana D. Jurchescu
- 13.2.Organic Electronic Devices
- Operation Principles / Oana D. Jurchescu
- 13.3. Materials for Organic Large-Area Electronics / Oana D. Jurchescu
- 13.4. Manufacturing Processes for Large-Area Electronics / Oana D. Jurchescu
- 13.4.1.Organic Devices Fabricated by Printing Methods / Oana D. Jurchescu
- 13.4.1.1. Soft Lithography / Oana D. Jurchescu
- Note continued: 13.4.1.2. Inkjet Printing / Oana D. Jurchescu
- 13.4.2. Spray Deposition for Organic Large-Area Electronics / Oana D. Jurchescu
- 13.4.2.1. Motivation and Technical Aspects for Spray Deposition / Oana D. Jurchescu
- 13.4.2.2. Top Electrodes Deposited by Spray Coating / Oana D. Jurchescu
- 13.4.2.3. Spray-Deposited Organic Thin-Film Transistors / Oana D. Jurchescu
- 13.4.2.4. Large-Area, Low-Cost Spray-Deposited Organic Solar Cells / Oana D. Jurchescu
- 13.5. Conclusions / Oana D. Jurchescu
- References / Oana D. Jurchescu
- 14.1. Introduction / Alberto Salleo
- 14.2. What are Traps in Organic Semiconductors and Where Do They Come From? / Alberto Salleo
- 14.3. Effect of Traps on Electronic Devices / Alberto Salleo
- 14.3.1. Transistors / Alberto Salleo
- 14.3.2. Light-Emitting Diodes / Alberto Salleo
- 14.3.3. Photovoltaics / Alberto Salleo
- 14.3.4. Sensors / Alberto Salleo
- 14.4. Detecting Traps in Organic Semiconductors / Alberto Salleo
- Note continued: 14.4.1. Optical Methods / Alberto Salleo
- 14.4.2. Scanning Probe Methods / Alberto Salleo
- 14.4.3. Electrical Methods / Alberto Salleo
- 14.4.4. Use of Electronic Devices / Alberto Salleo
- 14.5. Experimental Data on Traps in Organic Semiconductors / Alberto Salleo
- 14.5.1. Traps in Organic Single Crystals / Alberto Salleo
- 14.5.2. Traps in Polycrystalline Thin Films / Alberto Salleo
- 14.5.3. Traps in Conjugated Polymer Thin Films / Alberto Salleo
- 14.6. Conclusions and Outlook / Alberto Salleo
- References / Alberto Salleo
- 15.1. Introduction / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.2. Magnetoresistive Phenomena in Organic Semiconductors / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.2.1. Interface Phenomena
- The Role of Tunnel Barriers / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.2.2. Bulk Phenomena and Spin Transport / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- Note continued: 15.2.3. Interplay between Conductivity Switching and Spin Transport / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.3. Applications of Organic Spintronics / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.3.1. Sensor Applications / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.3.2. Memristive Phenomena in a Prototypical Spintronic Device / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 15.4. Future Developments / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- References / Alberto Riminucci / Mirko Prezioso / Patrizio Graziosi
- 16.1. Introduction / Jong-Ho Choi / Jeong-Do Oh / Hoon-Seok Seo
- 16.2. Neutral Cluster Beam Deposition Method / Jong-Ho Choi / Hoon-Seok Seo / Jeong-Do Oh
- 16.3.Organic Thin Films and Organic Field-Effect Transistors / Jeong-Do Oh / Hoon-Seok Seo / Jong-Ho Choi
- Note continued: 16.3.1. Morphological and Structural Properties of Organic Thin Films / Jong-Ho Choi / Hoon-Seok Seo / Jeong-Do Oh
- 16.3.2. Characterization of OFETs / Jeong-Do Oh / Hoon-Seok Seo / Jong-Ho Choi
- 16.3.3. Transport Phenomena / Jong-Ho Choi / Hoon-Seok Seo / Jeong-Do Oh
- 16.4.Organic Light-Emitting Field-Effect Transistors / Jeong-Do Oh / Hoon-Seok Seo / Jong-Ho Choi
- 16.4.1. Characterization of the Component OFETs of Ambipolar OLEFETs / Jong-Ho Choi / Hoon-Seok Seo / Jeong-Do Oh
- 16.4.2. Electroluminescence and Conduction Mechanism / Jeong-Do Oh / Hoon-Seok Seo / Jong-Ho Choi
- 16.5.Organic CMOS Inverters / Jong-Ho Choi / Hoon-Seok Seo / Jeong-Do Oh
- 16.5.1. Characterization of the Component OFETs of Organic CMOS Inverters / Jeong-Do Oh / Hoon-Seok Seo / Jong-Ho Choi
- 16.5.2. Realization of Air-Stable, Hysteresis-Free Organic CMOS Inverters / Jong-Ho Choi / Hoon-Seok Seo / Jeong-Do Oh
- 16.6. Summary / Hoon-Seok Seo / Jeong-Do Oh / Jong-Ho Choi