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1. | EXECUTIVE SUMMARY AND CONCLUSIONS |
1.1. | Purpose of this report |
1.2. | Editable (user-dedicated) electronics and electrics as smart material |
1.3. | Primary conclusions: what it is, winners and losers |
1.4. | Primary conclusions: general technology |
1.5. | Electronics and electrics as cuttable, formable reels or sheet |
1.6. | Primary conclusions: options for editing/ customising by user |
1.7. | Primary conclusions: technology specifics |
1.8. | Commercialisation timeline 2020-2040 |
1.9. | Addressable market forecasts: ten categories |
2. | INTRODUCTION |
2.1. | Overview |
2.2. | Some of the toolkit |
2.2.1. | User cuts, stretches, morphs, paints feedstock to purpose |
2.2.2. | Printed LEDs cut to shape and tailored function |
2.3. | Stretchable, editable electronics |
2.3.1. | Customisable stretchability |
2.3.2. | Reconfigurable stretchable systems for multifunctional electronics |
2.3.3. | Breathable, stretchable, wearable electronics |
2.3.4. | Customisable, stretchable, wearable self-powered sensors |
2.4. | Morphing materials |
3. | BATTERIES TO GO ANYWHERE |
3.1. | Folding textile batteries |
3.2. | Battery survives shot, bend, cut |
3.3. | Any shape anywhere printed batteries: Printed Energy |
3.4. | Voltabox free-form batteries |
4. | SUPERCAPACITORS TO GO ANYWHERE |
4.1. | Rollable, foldable supercapacitors |
4.2. | Spray-on pseudocapacitors |
5. | PHOTOVOLTAICS BECOMES A FEEDSTOCK FOR THE USER |
5.1. | Overview |
5.2. | Basics of flexible photovoltaics: Solar Frontier |
5.3. | Primary technologies of flexible photovoltaics |
5.4. | CIGS flexible photovoltaics: Flisom, Empa, Renovagen |
5.4.1. | Flisom "customizable flexible solar" |
5.4.2. | CIGS PV in action |
6. | SOLAR TAPE AND STRUCTURES |
6.1. | InfinityPV |
6.2. | Opvius and Armor |
7. | SPRAY-ON PHOTOVOLTAICS, TRIBOELECTRICS, HYDROGEN GENERATION |
7.1. | Overview |
7.2. | Spray-on and stick-on perovskite photovoltaics |
7.3. | Solterra retrofittable solar film from ink |
7.4. | Solar hydrogen paint |
7.5. | Spray-on thermoelectrics |
7.6. | Painted triboelectrics |
8. | CUSTOMIZABLE TRIBOELECTRIC NANOGENERATORS: MOTION HARVESTING |
8.1. | Introduction |
8.2. | 2020 review |
8.3. | Customizable TENG production using 3D printed imprinter |
8.4. | Editable circuits in textiles, film |
8.5. | Battery-free electronics: energy harvesting toys, biosensors, wearables |
9. | LAMINAR CIRCUITS TO CUT TO SHAPE |
9.1. | Wireless interface retrofit |
9.2. | Multifunctional editable materials in life sciences |
9.3. | Multifunctional washable fabrics and film |
9.3.1. | Self-powered wearable display |
9.4. | Customer configurable by stretching |
9.5. | Sensors in batteryless circuits and more |
10. | PAPERTRONICS |
10.1. | Circuits on and in paper |
10.2. | Paper supercapacitors: roll, fold and cut to purpose |
10.3. | Editable electronic kirigami |
11. | ELECTRICALLY SMART VEHICLE BODYWORK AND ELECTRONICS CASING |
11.1. | Overview |
11.2. | Stamping vehicles from reels of electrics |
11.3. | Possible evolution to vehicle bodywork from smart feedstock |
11.4. | Imperial College UK |
11.5. | Metal-organic frameworks |
12. | RECONFIGURABLE METAMATERIALS AND COMPOSITES |
12.1. | Reconfigurable metamaterials in 3D and 4D printing |
12.2. | Multifunctional polymer composites |
12.3. | Self-healing multifunctional materials |
12.4. | Polymer composites progress in 2020 |
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