Handbook of flexible organic electronics : materials, manufacturing and applications

Organic flexible electronics represent a highly promising technology that will provide increased functionality and the potential to meet future challenges of scalability, flexibility, low power consumption, light weight, and reduced cost. They will find new applications because they can be used with curved surfaces and incorporated in to a number of products that could not support traditional electronics. The book covers device physics, processing and manufacturing technologies, circuits and packaging, metrology and diagnostic tools, architectures, and systems engineering. Part one covers the production, properties and characterisation of flexible organic materials and part two looks at applications for flexible organic devices.

Related titles List of contributors Woodhead Publishing Series in Electronic and Optical Materials Part One. Properties and materials 1. Mechanics of curvature and strain in flexible organic electronic devices 1.1. Introduction 1.2. Stress and strain analyses 1.3. Failure under tensile stress 1.4. Failure under compressive stress 1.5. Mechanical test methods 1.6. Toward compliant and stretchable electronics 1.7. Conclusions 2. Structural and electronic properties of fullerene-based organic materials: density functional theory-based calculations 2.1. Introduction 2.2. Theoretical background 2.3. Structural transformations of fullerenes based on DFT calculations 2.4. Prototype impurities in fullerene crystals and electronic effects 2.5. Summary and future trends 3. Hybrid and nanocomposite materials for flexible organic electronics applications 3.1. Introduction 3.2. Production methods 3.3. Properties 3.4. Limitations 3.5. Electronics applications 3.6. Future trends 3.7. Sources of further information and advice 4. Organic polymeric semiconductor materials for applications in photovoltaic cells 4.1. Introduction 4.2. Polymeric electron donors for bulk-heterojunction photovoltaic solar cells 4.3. Fullerene and polymeric-based electron acceptors for bulk heterojunction photovoltaic solar cells 4.4. Hybrid structures of polymer, copolymer semiconductors with carbon nanostructures 4.5. Conclusions Part Two. Technologies 5. High-barrier films for flexible organic electronic devices 5.1. Introduction 5.2. Encapsulation of flexible OEs 5.3. Permeability mechanisms through barrier materials 5.4. Permeation measurement techniques 5.5. Advances in high-barrier materials 5.6. Conclusions 6. Advanced interconnection technologies for flexible organic electronic systems 6.1. Introduction 6.2. Materials and processes 6.3. Reliability 6.4. Summary and future trends 7. Roll-to-roll printing and coating techniques for manufacturing large-area flexible organic electronics 7.1. Introduction 7.2. Printing techniques 7.3. Coating techniques 7.4. Specialist coating techniques 7.5. Encapsulation techniques 7.6. Applications 7.7. Future trends 8. Integrated printing for 2D/3D flexible organic electronic devices 8.1. Introduction 8.2. Fundamentals of inkjet printing 8.3. Electronic inks 8.4. Vertically integrated inkjet-printed electronic passive components 8.5. Conclusions 9. In situ characterization of organic electronic materials using X-ray techniques 9.1. Introduction 9.2. Grazing incidence X-ray diffraction 9.3. Temperature-dependent studies 9.4. In situ X-ray studies 9.5. Conclusions 10. In-line monitoring and quality control of flexible organic electronic materials 10.1. Introduction 10.2. Fundamentals of spectroscopic ellipsometry 10.3. Characterization of organic electronic nanomaterials 10.4. Conclusions and future trends 11. Optimization of active nanomaterials and transparent electrodes using printing and vacuum processes 11.1. Introduction 11.2. Optimization of r2r printed active nanomaterials and electrodes 11.3. Combination of wet and vacuum techniques for OEs 11.4. Future trends 12. Laser processing of flexible organic electronic materials 12.1. Introduction 12.2. The physics of laser interaction with thin films 12.3. Laser systems and sources 12.4. Beam delivery assembly 12.5. Laser modification of materials and C surfaces 12.6. Laser ablation processes 12.7. Laser printing 12.8. Conclusions and future trends 13. Flexible organic electronic devices on metal foil substrates for lighting, photovoltaic, and other applications 13.1. Introduction 13.2. Substrate selection 13.3. Substrate preparation 13.4. TFTs for displays on metal foil 13.5. OLED lighting and photovoltaics on metal foil 13.6. Future trends Part Three. Applications 14. Smart integrated systems and circuits using flexible organic electronics: automotive applications 14.1. Introduction 14.2. Materials for integrated systems 14.3. Manufacturing processes 14.4. Automotive applications 14.5. Conclusions 15. Chemical sensors using organic thin-film transistors (OTFTs) 15.1. Introduction 15.2. Gas and vapour sensors 15.3. Humidity sensors 15.4. pH detection 15.5. Glucose detection 15.6. Deoxyribonucleic acid detection 15.7. Conclusions 16. Microfluidic devices using flexible organic electronic materials 16.1. Introduction 16.2. Microfluidics and electronics 16.3. Materials and fabrication techniques 16.4. Device examples 16.5. Summary 16.6. Future trends 17. Two-terminal organic nonvolatile memory (ONVM) devices 17.1. Introduction 17.2. Carbon nanotube (CNT)-based 2T-ONVM structures 17.3. Conclusion 18. Printed, flexible thin-film-batteries and other power storage devices 18.1. Introduction 18.2. The development of printed batteries 18.3. Basic design of printed batteries 18.4. Printing technologies and challenges 18.5. Properties of printed batteries 18.6. Conclusions and future trends Appendix: Patent applications on printed batteries Index Colour section plate captions