Boca Raton : , : CRC Press, , 2013

0-429-18609-6

1-58488-731-1

1 online resource (404 p.)

Chapman & Hall/CRC computer and information science series

DeyTamal K <1964-> (Tamal Krishna)

ShewchukJonathan

514/.223

Nets (Mathematics)

Numerical grid generation (Numerical analysis)

Triangulation

Electronic books.

Inglese

Description based upon print version of record.

Includes bibliographical references.

Front Cover; Contents; Preface; Chapter 1: Introduction; Chapter 2: Two-dimensional Delaunay triangulations; Chapter 3: Algorithms for constructing Delaunay triangulations; Chapter 4: Three-dimensional Delaunay triangulations; Chapter 5: Algorithms for constructing Delaunay triangulations in; Chapter 6: Delaunay refinement in the plane; Chapter 7: Voronoi diagrams and weighted complexes; Chapter 8: Tetrahedral meshing of PLCs; Chapter 9: Weighted Delaunay refinement for PLCs with small angles; Chapter 10: Sliver exudation; Chapter 11: Refinement for sliver exudation

Chapter 12: Smooth surfaces and point samplesChapter 13: Restricted Delaunay triangulations of surface samples; Chapter 14: Meshing smooth surfaces and volumes; Chapter 15: Meshing piecewise smooth complexes; Bibliography; Back Cover

"Going beyond, yet thoroughly rooted to theory, this book provides a comprehensive look at the algorithms that can produce quality Delaunay meshes through a paradigm called the Delaunay refinement. The authors describe meshing algorithms that can be built on the Delaunay refinement paradigm along with the involved mathematical

analysis. In addition to introducing the theoretical foundation of meshing, the text discusses practical issues associated with the use of these algorithms and explores new developments in guaranteed meshing. The book also includes pseudo code as well as downloadable computer programs for meshing"--

Weinheim, Germany : , : Wiley-VCH, , 2018

3-527-80488-9

3-527-80489-7

1 online resource (337 pages)

Advanced Nanocarbon Materials

621.381

Flexible electronics

Inglese

Cover -- Title Page -- Copyright -- Contents -- About the Series Editor -- Preface -- Chapter 1 Soft Composites with Tunable Optical and Electrical Properties -- 1.1 Introduction -- 1.2 Soft Color Composites -- 1.3 Hybrid Viscoelastic Polymer Composites -- 1.4 Elastomeric Conductive Composites -- 1.5 Conclusions and Future Perspectives -- Acknowledgments -- References -- Chapter 2 Organic Semiconductors for Transparent Electronics -- 2.1 Introduction -- 2.2 Optically Transparent Semiconductor Families -- 2.2.1 Thin‐film Transistors -- 2.2.2 Oligothiophenes -- 2.2.3 Fused Heteroacenes -- 2.2.4 Rylene and Fused Aromatic Dicarboximides -- 2.2.5 Other Semiconductors -- 2.3 Conclusions and Perspectives -- References -- Chapter 3 Flexible Carbon‐based Electronics: Flexible Solar Cells -- 3.1 Introduction -- 3.2 Applications -- 3.3 Device Physics -- 3.3.1 Structure and Operating Principle -- 3.3.2 Solar Cell Characteristics -- 3.4 New Materials -- 3.5 Flexible Electrodes -- 3.6 Processing -- 3.6.1 Laboratory Scale -- 3.6.2 Industrial Scale -- 3.6.3 Solar Modules -- 3.7 Summary and Outlook --

References -- Chapter 4 Development of Organic Field‐effect Transistors for Operation at High Frequency -- 4.1 Introduction -- 4.2 The Transition Frequency ft -- 4.2.1 Measurement Methods -- 4.3 High‐frequency Organic Field‐effect Transistors -- 4.3.1 Improvement of the Effective Charge Mobility -- 4.3.2 The Reduction of the Footprint -- 4.3.3 Achieving High‐frequency Operation at a Low Bias Voltage -- 4.3.4 Integration into Upscalable Fabrication Processes -- 4.4 Conclusions and Perspectives -- References -- Chapter 5 Graphene for Flexible Electronics -- 5.1 Introduction -- 5.2 Synthesis and Transfer Process -- 5.2.1 Chemical Vapor Deposition (CVD): Scalable Growth -- 5.2.2 Transfer Process -- 5.3 Applications -- 5.3.1 Transparent Electrodes.

5.3.1.1 Touch Screen/Panel -- 5.3.1.2 Organic Light‐Emitting Diodes -- 5.3.1.3 Photovoltaic Device -- 5.3.2 Field‐effect Transistors -- 5.3.3 Sensors -- 5.3.4 Nanogenerator for Energy Harvesting -- 5.4 Conclusions and Perspectives -- References -- Chapter 6 Printing 2D Materials -- 6.1 Introduction -- 6.2 Printing Techniques -- 6.2.1 Spin Coating -- 6.2.2 Blade Coating -- 6.2.3 Rod Coating -- 6.2.4 Spray Coating -- 6.2.5 Screen Printing -- 6.2.6 Flexographic Printing -- 6.2.7 Gravure Printing -- 6.2.8 Inkjet Printing -- 6.3 Formulation and Characterization of Electronic Inks -- 6.3.1 Ink Rheology and Surface Chemistry -- 6.3.2 Dispersion of Functional Layered Materials -- 6.4 Exfoliation of Layered Crystals -- 6.4.1 Ultrasonication -- 6.4.2 Ball Milling -- 6.4.3 Shear Exfoliation -- 6.4.4 Microfluidization -- 6.5 Stabilization of Exfoliated Flakes -- 6.5.1 Surfactants -- 6.6 Formulation: From Dispersion to Ink -- 6.6.1 The Rheology of Inks -- 6.7 Printing and Coating of 2D‐crystal‐based Inks -- 6.7.1 Spin Coating -- 6.7.2 Blade and Rod Coating -- 6.7.3 Spray Coating -- 6.7.4 Screen Printing -- 6.7.5 Inkjet Printing -- 6.7.6 Characterization Techniques -- 6.8 Applications -- 6.8.1 Printed Electronics -- 6.8.2 Printed Optoelectronics -- 6.8.3 Sensors and Wearable Devices -- 6.8.4 Energy Devices -- 6.8.5 Printed THz Devices -- 6.9 Outlook and Future Perspectives -- Acknowledgments -- References -- Chapter 7 Characterization of Graphene Flexible Materials and Displays -- 7.1 Introduction to Display Systems -- 7.2 Graphene/Flexible Polymer Electrodes -- 7.2.1 Sheet Resistance and Transmittance of Graphene/Flexible Polymer Electrodes -- 7.2.2 Mechanical Robustness of Graphene/Flexible Polymer Electrodes -- 7.3 Graphene‐based Flexible Displays -- 7.4 Outlook -- References -- Chapter 8 AMOLED Display Technology and Applications -- 8.1 Introduction.

8.2 Commercial Flexible AMOLED Displays -- 8.3 OLED Displays -- 8.3.1 Structure and Electro‐optic Behavior -- 8.3.2 Lifetime Effects in OLEDs -- 8.4 AMOLED Display Design -- 8.4.1 TFT Technologies for Flexible AMOLED Displays -- 8.4.1.1 Polysilicon TFTs -- 8.4.1.2 Metal Oxide TFTs -- 8.4.2 AMOLED Pixel Design -- 8.4.3 Integrated Display Drivers -- 8.5 Substrates and Barrier Coatings -- 8.5.1 Substrates -- 8.5.2 Barrier Coatings -- 8.5.3 Additional Layers -- 8.5.4 Characterization of Flexibility -- 8.6 The Future of Flexible AMOLED Displays -- References -- Chapter 9 Flexible Batteries -- 9.1 Introduction -- 9.2 Electrochemical Power Sources - Theoretical Basics -- 9.2.1 Conventional (lithium‐ion) battery build‐up -- 9.3 Basic Material Concepts for Flexible Energy Storage Systems -- 9.3.1 Flexible Electrodes -- 9.3.2 Flexible Electrolyte -- 9.3.3 Flexible Packaging -- 9.4 Basic Design Concepts for Flexible Energy Storage Systems -- 9.4.1 Thin‐film/Printed Batteries -- 9.4.2 Fiber‐shaped/Cable‐type Batteries -- 9.4.3 Embedded Batteries -- 9.5 Summary and Outlook -- References -- Chapter 10 Flexible Organic Bioelectronics and Biosensors -- 10.1 Introduction -- 10.2 Organic Material -- 10.3

Flexible Organic Electronics for Biology -- 10.3.1 OTFTs -- 10.3.1.1 OFET Sensors -- 10.3.1.2 OECTs Sensors -- 10.3.2 Organic Electrodes -- 10.3.2.1 Biological Sensing -- 10.3.2.2 Neural Recording/Stimulation -- 10.3.2.3 Others -- 10.3.3 e‐Textiles -- 10.4 Conclusion -- References -- Index -- EULA.