Stretchable electronics

On a daily basis, our requirements for technology become more innovative and creative and the field of electronics is helping to lead the way to more advanced appliances. This book gathers and evaluates the materials, designs, models, and technologies that enable the fabrication of fully elastic electronic devices that can tolerate high strain. Written by some of the most outstanding scientists in the field, it lays down the undisputed knowledge on how to make electronics withstand stretching. This monograph provides a review of the specific applications that directly benefit from highly compliant electronics, including transistors, photonic devices, and sensors. In addition to stretchable devices, the topic of ultraflexible electronics is treated, highlighting its upcoming significance for the industrial-scale production of electronic goods for the consumer. Divided into four parts covering: * Theory * Materials and Processes * Circuit Boards * Devices and Applications An unprecedented overview of this thriving area of research that nobody in the field - or intending to enter it - can afford to miss.

PREFACE PART I: Theory THEORY FOR STRETCHABLE INTERCONNECTS Introduction Mechanics of Stretchable Wavy Ribbons Mechanics of Popup Structure Mechanics of Interconnects in the Noncoplanar Mesh Design Concluding Remarks MECHANICS OF TWISTABLE ELECTRONICS Introduction Postbuckling Theory Postbuckling of Interconnect under Twist Symmetric Buckling Mode Antisymmetric Buckling Mode Discussion and Concluding Remarks PART II: Materials and Processes GRAPHENE FOR STRETCHABLE ELECTRONICS Introduction Production of Graphene Films Fabrication of Graphene Films on Substrates Applications in Flexible and Stretchable Electronics Concluding Remarks STRETCHABLE THIN-FILM ELECTRONICS Introduction Silicone Rubber as a Substrate Mechanical Architecture Stretchable Metallization Integrated Stretchable Thin-Film Devices Outlook STRETCHABLE PIEZOELECTRIC NANORIBBONS FOR BIOCOMPATIBLE ENERGY HARVESTING Energy Harvesting and Piezoelectric Materials PZT Nanofabrication and Interfacing with Stretchable Substrates Piezoelectric Characterization and Electrical Measurements Summary PART III: Circuit Boards MODELING OF PRINTED CIRCUIT BOARD INSPIRED STRETCHABLE ELECTRONIC SYSTEMS Technology Development Considerations Modeling and Simulation MATERIALS FOR STRETCHABLE ELECTRONICS COMPLIANT WITH PRINTED CIRCUIT BOARD FABRICATION Introduction TECHNOLOGIES AND PROCESSES USED IN PRINTED CIRCUIT BOARD FABRICATION FOR THE REALIZATION OF STRETCHABLE ELECTRONICS Lamination Technology Molding Technology RELIABILITY AND APPLICATION SCENARIOS OF STRETCHABLE ELECTRONICS REALIZED USING PRINTED CIRCUIT BOARD TECHNOLOGIES Application Considerations Reliability Application Scenarios PART IV: Devices and Applications STRETCHABLE ELECTRONIC AND OPTOELECTRONIC DEVICES USING SINGLE-CRYSTAL INORGANIC SEMICONDUCTOR MATERIALS Introduction Stretchable Circuits Application of Stretchable Designs to Microscale Inorganic Light Emitting Diodes (?-ILEDs) Biomedical Applications of Stretchable Electronics and Optoelectronics Stretchable Digital Imagers and Solar Modules Conclusions STRETCHABLE ORGANIC TRANSISTORS Introduction Perforated Organic Transistor Active Matrix for Large-Area, Stretchable Sensors Rubber-Like Stretchable Organic Transistor Active Matrix Using Elastic Conductors Rubber-Like Organic Transistor Active Matrix Organic Light-Emitting Diode Display Future Prospects POWER SUPPLY, GENERATION, AND STORAGE IN STRETCHABLE ELECTRONICS Introduction Radio Frequency Power Supplies Power Generation Power Storage Summary SOFT ACTUATORS Introduction Conducting Polymers Ionic Polymer Metal Composites (IPMCs) Nanocarbon Actuators Applications Conclusion ELASTOMER-BASED PRESSURE AND STRAIN SENSORS Introduction A Brief Elastomers Overview Important Sensor Characteristics Elastomeric Force Sensors Active Pressure/Strain Sensors Systems Applications Outlook CONFORMABLE ACTIVE DEVICES Introduction Printing Processes for Organic TFTs Sensing and Memory Devices Based on Piezoelectric Polymer Electronic Circuits Curved Conformal Devices by a Cut-and-Bend Approach Summary STRETCHABLE NEURAL INTERFACES Introduction Overview of MEAs Classes of SMEAs Common Limitations for All SMEAs Future Directions in Stretchable Neural Interfaces Conclusion BIO-BASED MATERIALS AS TEMPLATES FOR ELECTRONIC DEVICES Introduction Polysaccharide-Based Templates Protein-Based Templates DNA Templates Virus Templates: Tobacco Mosaic Virus and M13 Bacteriophage Summary ORGANIC INTEGRATED CIRCUITS FOR EMI MEASUREMENT Introduction Stretchable EMI Measurement Sheet Silicon CMOS LSI for EMI Detection Experimental Results and Discussion Conclusion INDEX