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Table of Contents 1. EXECUTIVE SUMMARY AND CONCLUSIONS
1.1. Introduction
1.2. What is it?
1.3. Tackling urgent problems
1.4. Primary benefits
1.5. Maturity by applicational sector
1.6. Objectives and benefits
1.7. Materials and processes currently favoured
1.8. Smart skin
1. EXECUTIVE SUMMARY AND CONCLUSIONS
1.1. Introduction
1.2. What is it?
1.3. Tackling urgent problems
1.4. Primary benefits
1.5. Maturity by applicational sector
1.6. Objectives and benefits
1.7. Materials and processes currently favoured
1.8. Smart skin
1.9. Component types being subsumed
1.10. Future proof
1.11. How to make structural electronics
1.11.1. A host of new technologies
1.12. Market forecasts
1.13. Energy harvesting in general
1.14. Structural as wireless
1.15. Components designed for embedding in load-bearing structures.
1.16. GES Aviation
1.17. News in 2016 - Bat-inspired design for Micro Air Vehicles
2. APPLICATIONS OF STRUCTURAL ELECTRONICS
2.1. Aerospace
2.2. Cars
2.2.1. BMW Germany and Nanyang TU Singapore
2.2.2. Funding for development of lightweight solar modules on vehicles
2.3. Consumer goods and home appliances
2.4. Bridges and buildings
2.5. Structural electronics on the ground
2.5.1. Generating electricity
2.5.2. Sensing
2.6. Solar Roads
2.6.1. SolaRoad Netherlands
3. KEY FORMATS AND ENABLING TECHNOLOGIES
3.1. Basics
3.2. Detailed analysis
3.3. NASA leading the way
3.4. Early progress at plastic electronic
4. SMART SKIN
4.1. Description
4.2. Wire and cable smart cladding
4.3. Many other examples
4.3.1. Hybrid Piezo Photovoltaic Harvesting
4.4. NASA open coil arrays as electronic smart skin
4.5. American Semiconductor CLAS systems
4.6. BAE Systems UK: smart skin for aircraft then cars and dams
4.7. Graphene composite may keep wings ice-free
4.8. Composites evolve to add electronic functionality
4.8.1. Reasons, achievements, timeline 1940-2030
5. SOME KEY ENABLING TECHNOLOGIES
5.1. Smart materials
5.1.1. Comparisons, uses
5.1.2. Fiat car of the future
5.2. Printed and flexible electronics
5.2.1. Introduction and examples
5.2.2. Basic printed modules
5.2.3. Bendable then conformal photovoltaics
5.2.4. Printed electronics in structural electronics
5.3. 3D printing
5.3.1. New materials
5.3.2. Adding electronic and electrical functions
5.3.3. The future
5.3.4. Printed graphene batteries
5.4. Spray on solar cells
5.5. Multi-step drop-casting of conformal film
5.6. Origami zippered tube
5.7. Smallest synthetic lattice in the world
6. STRUCTURAL SUPERCAPACITORS AND BATTERIES
6.1. Many forms of structural supercapacitor
6.1.1. Queensland UT supercap car body
6.1.2. Vanderbilt University structural supercapacitor
6.1.3. Imperial College London/ Volvo structural supercapacitor for car
6.2. Fundamentals
6.3. Structural batteries and fuel cells
6.4. Printable solid-state Lithium-ion batteries
7. BUILDING INTEGRATED PHOTOVOLTAICS (BIPV)
7.1. History
7.2. Definition and reason for new interest
7.3. Evolution
7.4. Comparison of options now and in future
7.5. Rigid to flexible to conformal and stretchable
7.6. OPV and DSSC compared
7.6.1. Slow rollout
7.7. Dye Sensitised Solar Cells for BIPV
7.7.1. Dye Solar Cell Technology
7.7.2. Sandia Laboratories
7.7.3. Saule, Poland
7.8. Latest CIGS progress
7.9. Huge improvement possible
7.10. Solar - takeoff soon; dominance 2050
7.11. Heat energy storage device
7.12. White solar panels vanish into buildings
7.13. World's first BIOPV concrete façade installation
7.14. Successful start of pilot project for energy self-sufficient air dome
7.15. Concrete delivers solar energy
8. COMPANY PROFILES
8.1. Boeing, USA
8.2. Canatu, Finland
8.3. Faradair Aerospace UK
8.4. Local Motors, USA
8.5. Neotech, Germany
8.6. Odyssian Technology, USA
8.7. Paper Battery Co., USA
8.8. Soligie, USA
8.9. TactoTek, Finland
8.10. T-Ink, USA
9. RECENT INTERVIEWS
9.1. Prof Jennifer Lewis' Group at Harvard University and Voxel8
9.2. Supercapacitor company visits in late 2014
9.2.1. DuPont, Nippon ChemiCon
9.2.2. Taiyo Yuden
9.3. Photovoltaics and OLED company visits in late 2014
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