This report is no longer available. Click here to view our current reports or contact us to discuss a custom report.
If you have previously purchased this report then please use the download links on the right to download the files.
Wearable Technology Materials 2015-2025
Wearable technology potential for chemical / intermediate material makers. Functional materials.
Show All
Description
Contents, Table & Figures List
FAQs
Pricing
Related Content
This report concerns a new market for wearable electronics that awaits those prepared to make formulations and intermediate materials for the new 2D and 3D electronic printing, in-mold electronics and other processes. These and similar processes discussed in the report are being adopted over the coming decade because wearable electronics is changing its form radically, the better to comply with physical and economic needs as the report explains.
The change of materials, suppliers and processes is driven by the fact that the new e-skin patches, e-textiles, stretchable, tightly rollable devices and so on cannot be made with the old "components in a box" approach. Electronics must become transparent or disappear into everyday objects such as spectacle frames for example. Suppliers are needed for formulations and intermediate materials at the heart of this new electronics and electrics. Premium pricing awaits.
The report evaluates how wearable electronics offers these suppliers over $100 billion in cumulative material sales over the coming decade. This report is written for these suppliers as the only comprehensive, up-to-date analysis of the whole scene that focuses on materials needed rather than the finished devices. It has many figures and tables of explanation, analysis and market value prediction for 2015-2025 for both the materials and the complete devices.
The appraisal and prediction is based on interviews worldwide in many languages, searches of proprietary IDTechEx databases and other sources and recent conference presentations, not least those at the successful recent IDTechEx events on the subject. The report is global in reach and sourced by recent extensive travel to universities, research centres, events and companies worldwide. It assesses the activities of key players and it evaluates the gaps in the emerging materials market for wearable electronics and electrics. What is the need for inorganic and organic compounds and composites by molecule and atom and for which allotropes of carbon? In what form such as ink or pre-coated film? It is all here. The report forms part of a series of reports on markets and technology for the booming market for wearable electronics. Respectively they cover the whole business, that for animals and the enabling e-textiles, stretchable electronics, printed electronics, 3D printing, structural electronics and energy harvesting.
Analyst access from IDTechEx
All report purchases include up to 30 minutes telephone time with an expert analyst who will help you link key findings in the report to the business issues you're addressing. This needs to be used within three months of purchasing the report.
Further information
If you have any questions about this report, please do not hesitate to contact our report team at research@IDTechEx.com or call one of our sales managers:
ASIA: +44 1223 810259
| 1. | EXECUTIVE SUMMARY AND CONCLUSIONS |
| 1.1. | Total wearable technology market human and animal and the electronically functional material value % and $ billion 2015-2025 |
| 1.1. | Total wearable technology market human and animal and the electronically functional material value % and $ billion 2015-2025 ex-factory |
| 1.1. | Premium-priced new materials |
| 1.2. | Organic, inorganic and composite in new forms |
| 1.2. | How and why wearable technology will adopt smart materials and totally new production processes |
| 1.2. | Trends of technology towards wearable |
| 1.3. | New wearable products but made using old components-in-a-box technology |
| 1.3. | Wearable technology trends and examples of materials needs resulting |
| 1.3. | Assembly technologies |
| 1.4. | Survey results of interest to materials suppliers |
| 1.4. | The 37 present and future device families |
| 1.4. | The two main types of wearable technology, their typical characteristics (though not all are exhibited by any one realisation) with examples and allied subjects. The Adidas fitness monitoring sports bra at top is comfortable and s |
| 1.4.1. | Analysis |
| 1.4.2. | Highest volume formulations: commoditisation risk |
| 1.4.3. | Broadest use: de-risking investment |
| 1.5. | Going against the trend: smart wristwear compared to phones getting bigger |
| 1.5. | The IDTechEx forecasts for wearable electronics for humans and animals 2015-2025 is given below in $ billion ex-factory rounded with human forecasts broken down by sector |
| 1.5. | The global device market value by applicational sector 2015-2025 |
| 1.5.1. | Global device market value 2015-2025 |
| 1.6. | Probable scenario for functional materials breakdown by market size 2025 |
| 1.6. | Number of new device families using elemental or mildly alloyed aluminium, copper, gold, silicon and silver giving % of 37 device families analysed and typical functional form over the coming decade |
| 1.7. | The anions or metals in the most popular inorganic compounds in the new electronics by number of device families using them and percentage of the 37 device families (there is overlap for multi-metal formulations). Main functional |
| 1.7. | Probable functional materials including intermediate materials by type in wearable electronics 2025 |
| 1.8. | The incidence of the allotropes of carbon that are most widely being used, at least experimentally, for the 37 types of new electronics and electrics giving functional form and % and number of surveyed devices involved |
| 1.9. | The families of functional organic compound that are most widely being used or investigated for the new electronics as % of sample and number of device families using them. This excludes substrates. They are mainly polyester. |
| 1.10. | IDTechEx forecast for human vs animal wearable electronics 2015-2025 in $ billion |
| 1.11. | IDTechEx forecast for wearable electronics for humans by sector 2015-2025$ billion ex-factory rounded |
| 1.12. | Approximate ex-factory price sensitivity of wearable electronics by applicational sector and number sold |
| 1.13. | Price sensitivity of wearable electronics by example vs number sold |
| 1.14. | Probably functional formulations, intermediate materials and key components by type in wearable electronics 2025 |
| 2. | CHEMICALS AND INTERMEDIATES FOR FUTURE WEARABLE ELECTRONICS |
| 2.1. | Introduction |
| 2.1. | Healthcare example of flexible modules being used to create a wearable device based on System on Chip SoC. |
| 2.1. | Comparisons of growing sector needs and solutions |
| 2.1.1. | The electronics value chain favors materials suppliers |
| 2.1.2. | Electronic capabilities required |
| 2.2. | Materials needed for the new electronics |
| 2.2. | Comparisons of mature sector needs and solutions |
| 2.2. | Trend to III-V compounds for highest performance flexible semiconductors. |
| 2.2.1. | Introduction |
| 2.2.2. | Elements and compounds |
| 2.2.3. | Metals most widely needed - survey result |
| 2.2.4. | Inorganic compounds most widely needed - survey result |
| 2.2.5. | Importance of III-IV compounds |
| 2.2.6. | Allotropes of carbon most widely needed - survey result |
| 2.2.7. | Organic compounds most widely needed - survey results |
| 2.3. | Survey results for lithium salts |
| 2.3. | Open-Platform Flexible thermoelectric generator TEG |
| 2.3. | Description and images of 37 families of new and growing electronics and electrics suitable for wearable technology |
| 2.4. | Examples of elements and compounds most widely needed for growth markets in the new electronics and electrics over the coming decade |
| 2.4. | Less prevalent or less established formulations |
| 2.5. | 16 functional elements and compounds used in 37 functions of the newer wearable and other electronics |
| 2.6. | Four families of carbon allotrope needed in the new electronics and electrics |
| 2.7. | Organic materials used and researched for the 37 families of new electronics and electrics |
| 2.8. | Manufacturers and putative manufacturers of lithium-based rechargeable batteries showing country, cathode and anode chemistry, electrolyte form, case, targeted applicational sectors and sales relationships and successes by vehicle |
| 2.9. | Examples of relatively less prevalent or less established formulations than those examined earlier |
| 3. | STRUCTURAL ELECTRONICS FOR WEARABLES |
| 3.1. | Introduction |
| 3.1. | Benefits and challenges of structural electronics in wearables that materials suppliers can address |
| 3.1. | Wearable electronics made using conventional electronics today |
| 3.2. | Some possible future structures of multilayer multifunctional electronic smart skin on wearables |
| 3.2. | Criteria for a component to be most suitable for subsuming into SE |
| 3.2. | Megatrend |
| 3.3. | Benefits and challenges |
| 3.3. | Structure and electronic functions of structural electronics in wearables feasible now or soon. |
| 3.3. | Printed electronics power module developed under the European Community FACESS project |
| 3.4. | Types of early win and longer term project involving printed electronics 1995-2025 |
| 3.4. | Examples of smart materials and their functions, challenges and potential uses in structural electronics |
| 3.4. | Smart skin |
| 3.5. | Rollout |
| 3.5. | Enabling technologies for present and future structural electronics that will be applied to wearables, often with other applications coming first |
| 3.5. | Hype cycle of 3DP applications |
| 3.6. | Some of the enabling technologies for structural electronics and relationships between them |
| 3.6. | Some key enabling technologies |
| 3.6.1. | Smart materials |
| 3.7. | Printed and flexible electronics |
| 3.7. | NASA nanotechnology roadmaps |
| 3.7.1. | Introduction and examples |
| 3.7.2. | Basic printed modules |
| 3.7.3. | Printed electronics in structural electronics |
| 3.7.4. | 2D titanium carbide |
| 3.8. | 3D printing |
| 3.8. | NASA nanomaterials roadmap |
| 3.8.1. | Description and benefits |
| 3.8.2. | 3D printing materials |
| 3.8.3. | New 3DP materials |
| 3.8.4. | Adding electronic and electrical functions |
| 3.8.5. | The future |
| 3.8.6. | Printed graphene batteries |
| 3.9. | Detailed analysis |
| 3.9. | NASA nanosensor roadmap |
| 3.10. | NASA biomimetics and bio-inspired systems |
| 3.10. | NASA leading the way |
| 4. | E-TEXTILES |
| 4.1. | Why? What? |
| 4.1. | How the common terms soft circuits, printed electronics, wearable electronics, smart textiles and e-textiles relate. The term electronics includes electrics |
| 4.1. | Some potential benefits and uses of weavable fibers that are inherently electronic or electric, the only modest commercial success being shown in green. |
| 4.2. | Possible timeline for inherently electronic/ electrical woven fibers in mass production. |
| 4.2. | Evolution expected to occur 2015-2025 for electronics and electrics distributed through textiles |
| 4.2. | Ultimate dream |
| 4.3. | Harsh reality |
| 4.3. | e-fibers for weaving compared to fiber optics, nanotubes and nanofibers. |
| 4.3. | Examples of smart textiles not reliant on fibers that are inherently electronic or electric. |
| 4.4. | The evolution of the physical structure of electronics with the aspects covered in this report - e-textiles and precursor products - highlighted in green. |
| 4.4. | Lumitex flexible woven fiber optic panels suitable for wearables |
| 4.4. | Road map |
| 4.5. | What it is not: a materials appraisal |
| 4.5. | e-fiber projects by country |
| 4.5.1. | General |
| 4.6. | Woven not for apparel |
| 4.6. | e-fiber projects by function |
| 4.6.1. | Example: Lumitex woven fiber optic panels |
| 4.7. | Challenges and opportunities |
| 4.7. | Example of transition envisaged from wearable devices to wearable e-textiles. |
| 4.7.1. | Overview |
| 4.7.2. | Main materials used for textile electronics of all types |
| 4.8. | Results of survey of e-fiber projects for e-textiles |
| 4.8. | Some of the possibilities from combining the best of disposable and laundry tags on apparel |
| 4.9. | Nothing inevitable about e-fibers |
| 4.10. | Potential benefits of e-fibers |
| 4.11. | Timeline for e-fibers |
| 4.12. | Examples of e-textiles not reliant on e-fibers |
| 4.13. | Poor alignment of development programs to addressable market |
| 4.13.1. | Disposable vs washable |
| 4.13.2. | Woven and flexible, washable tags |
| 4.13.3. | CNT coating of weavable fiber supercapacitors |
| 4.13.4. | CNT coating of weavable fiber for achieving improved conductivity. |
| 4.13.5. | Vacuum deposited organics on thread |
| 4.13.6. | Zinc oxide nanowire coating of weavable fibers for piezoelectricity |
| 4.13.7. | Product integration and manufacturing technology |
| 5. | STRETCHABLE ELECTRONICS |
| 5.1. | Introduction |
| 5.1. | The islands in elastomer approach to stretchable electronics |
| 5.2. | Stretchable LED display |
| 5.2. | Holst Centre Netherlands |
| 5.3. | DuPont USA |
| 5.3. | DuPont capability - some examples |
| 6. | COMPANY PROFILES |
| 6.1. | Adidas/Textronics |
| 6.2. | Bando Chemical Industries |
| 6.3. | Fujikura Kasei Co Ltd |
| 6.4. | Grafen Chemical Industries |
| 6.5. | GSI |
| 6.6. | Paper Battery |
| 6.7. | Samsung |
| 6.8. | Sekisui Chemical Co Ltd |
| 6.9. | Soligie |
| 6.10. | Sumitomo Chemical and CDT |
| 6.11. | T-Ink |
| IDTECHEX RESEARCH REPORTS | |
| IDTECHEX CONSULTANCY | |
| TABLES | |
| FIGURES |
Over $100 billion will be spent on materials for wearable electronics over the coming decade.
Report Statistics
| Pages | 189 |
|---|---|
| Tables | 25 |
| Figures | 38 |
| Forecasts to | 2025 |
Customer Testimonial
"IDTechEx consistently provides well-structured and comprehensive research reports, offering a clear and holistic view of key trends... It's my first go-to platform for quickly exploring new topics and staying updated on industry advancements."