Large Area and Flexible Electronics

Beschreibung

InhaltsangabeOverview PART I: Materials POLYMERIC AND SMALL-MOLECULE SEMICONDUCTORS FOR ORGANIC FIELD-EFFECT TRANSISTORS Introduction Organic Semiconductor Structural Design ThinFilm Transistor Applications pChannel Semiconductors nChannel Semiconductors Ambipolar Semiconductors Conclusions METALOXIDE THINFILM TRANSISTORS FOR FLEXIBLE ELECTRONICS Introduction MetalOxide TFTs SolutionProcessed MO Thin Films LowTemperatureProcessed MO TFTs for Flexible Electronics Summary CARBON NANOTUBE THIN-FILM TRANSISTORS Introduction Individual SWCNTs and SWCNT Thin Films Chemical Vapor Deposition Growth of SWCNT TFTs SolutionBased Methods for SWCNT TFTs Inkjet Printing of Flexible SWCNT TFTs Fabrication Schemes for High-Performance Inkjet-Printed SWCNT TFTs Inkjet Printing of SWCNT CMOS Inverters Inkjet Priting of Aligned SWCNT Films Conclusion ORGANIC SINGLE-CRYSTALLINE SEMICONDUCTORS FOR FLEXIBLE ELECTRONICS APPLICATIONS Introduction Electronic and Structural Properties of Single Crystals Crystallization Techniques SingleCrystal Flexible Electronic Devices Strategies for Flexible Organic Single-Crystal Device Fabrication Conclusions SOLUTIONPROCESSABLE QUANTUM DOTS Introduction Optimization of the Colloidal Synthesis of Quantum Dots by Selection of Suitable Solvents, Ligands, and Precursors LargeScale Synthesis of Quantum Dots Surface Chemistry of Quantum Dots PostSynthetic Chemical Modification of Nanocrystals Conclusions and Outlook INORGANIC SEMICONDUCTOR NANOMATERIALS FOR FLEXIBLE ELECTRONICS Introduction Characteristics and Synthesis of Inorganic Semiconducting NMs Applications in Flexible Electronics Concluding Remarks DIELECTRIC MATERIALS FOR LARGE-AREA AND FLEXIBLE ELECTRONICS Introduction General Polymer Dielectrics CrossLinked Polymer Dielectrics Highk Polymer Dielectrics Electrolyte Gate Dielectrics SelfAssembled Molecular Layer Dielectrics Hybrid Dielectrics SolGel Highk Inorganic Dielectrics Summary and Outlook ELECTROLYTEGATING ORGANIC THIN FILM TRANSISTORS Introduction Electrolyte Gated OTFT Operation Mechanisms Electrolyte Materials OTFTs Gated with Electrolyte Dielectrics Circuits Baed on Electrolyte-Gated OTFTs Conclusions VAPOR BARRIER FILMS FOR FLEXIBLE ELECTRONICS Introduction ThinFilm Permeation Barrier Layers Permeation through Inorganic Thin Films TimeResolved Measurements on Barrier Layers Mechanical Limitations of Inorganic Films Mechanics of Films on Flexible Substrates Summary LATEST ADVANCES IN SUBSTRATES FOR FLEXIBLE ELECTRONICS Introduction Factors Influencing Film Choice Film Property Set Summary of Key Properties of Base Substrates Planarizing Coatings Examples of Film in Use Concluding Remarks PART II: Devices and Applications INKJET PRINTING PROCESS FOR LARGE AREA ELECTRONICS Introduction Dynamics of Jet Formation Ink Rheology: Non-Newtonian Liquids Dynamics of Drop Impact and Spreading Applications of Inkjet Printing for Large-Area Electronics Summary INKJET PRINTED ELECTRONIC CIRCUITS BASED ON ORGANIC SEMICONDUCTORS Printed Organic Electronics CMOS Technology HighSpeed Organic CMOS Circuits Conclusions LARGEAREA, PRINTED ORGANIC CIRCUITS FOR AMBIENT ELECTRONICS Introduction Manufacturing Process and Electrical Characteristics Demonstration Future Prospects POLYMER AND ORGANIC NONVOLATILE MEMORY DEVICES Introduction Resistive Switching Memories Charge Storage in Transistor Gate Dielectric Polymer Ferroelectric Devices Conclusions FLEXIBLE DISPLAYS Introduction Flexible Substrates Display Mode ThinFilm Transistor AMOLED Panel with Printing Technology Fabrication of the OLED and AMOLED Panel Future Prospects FLEXIBLE ORGANIC SOLAR CELLS FOR SCALABLE, LOW-COST PHOTOVOLTAIC ENERGY CONVERSION Overview of Organic Photovoltaic (OPV) Cells Efforts toward Realization of Flexible OSCs Flexible OSCs for High-Throughput Production: A Printing-Based Approac

Autorenporträt

Mario Caironi is a Tenure Track Researcher at the Center for Nano Science and Technology (CNST) in Milan, Italy, of the Istituto Italiano di Tecnologia. He obtained his PhD in 2007 from the "Politecnico di Milano" and then joined Prof. Henning Sirringhaus' group at the Cavendish Laboratory in Cambridge, UK, to work on inkjet-printed, downscaled organic field-effect transistors (OFET) and on charge injection and transport in high-mobility polymers. In 2010 he was appointed as a Team Leader at CNST and entered tenure track in 2014 in the same institution. His current research interests are on direct-writing and roll-to-roll printing processes for organic and hybrid micro- and opto-electronics, on the device physics of OFETSs and on organic thermoelectrics. YongYoung Noh is Associate Professor in the Department of Energy and Materials Engineering at Dongguk University in Seoul, Republic of Korea. He received his PhD in 2005 from the Gwangju Institute of Science and Technology (GIST), Republic of Korea, and then worked at the Cavendish Laboratory in Cambridge, UK, as a postdoctoral associate with Prof. Henning Sirringhaus from 2005 t0 2007. Afterwards, he worked at the Electronics and Telecommunications Research Institute (ETRI), Republic of Korea, as a senior researcher from 2008 to 2009, and at Hanbat National University as assistant professor from 2010 to 2012. YongYoung Noh has received Merck Young Scientist Award (2013) and Korea President Award (2014). He has expertise in materials, process and device physics of organic and printed electronics for flexible electronics, especially printed OFETs, carbon nanotube or oxide TFTs and OLEDs.

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