Summary

The Global Market for Wearable Electronics and Sensors 2025-2035 provides comprehensive analysis of the rapidly evolving wearable technology industry, covering everything from consumer devices to medical applications and advanced electronic textiles. This extensive report examines key market trends, technological developments, and growth opportunities across the entire wearable electronics ecosystem. The wearables market continues to experience significant growth, driven by innovations in flexible electronics, sensor technologies, and advanced materials. The report provides detailed insights into major segments including smartwatches, fitness trackers, smart clothing, medical devices, and augmented/virtual reality headsets. With the integration of artificial intelligence, improved battery technology, and miniaturization of components, wearable devices are becoming increasingly sophisticated and capable of collecting and analyzing complex biometric data.

Key areas analyzed include:

• Comprehensive coverage of wearable form factors including smart watches, bands, glasses, clothing, patches, rings, hearables, head-mounted displays, jewelry, and smart insoles
• Detailed analysis of sensor technologies including motion, optical, force, strain, chemical, and biosensors
• Manufacturing methods and materials including printed electronics, 3D electronics, flexible substrates, and advanced integration techniques
• Medical and healthcare applications from continuous glucose monitoring to electronic skin patches
• Gaming and entertainment applications focusing on AR/VR/MR devices
• Electronic textiles (e-textiles) and smart apparel developments
• Energy storage and harvesting solutions for wearable devices

The report provides extensive market forecasts from 2025-2035, analyzing volume and revenue projections across different device categories and application segments. It examines key market drivers including:

• Growing demand for continuous health monitoring and preventive healthcare
• Increasing adoption of fitness tracking and sports performance analysis
• Rising interest in augmented and virtual reality applications
• Advancements in flexible electronics and sensor technologies
• Integration of AI and machine learning capabilities
• Development of improved power solutions and energy harvesting
• Expansion of IoT and connected device ecosystems

Key technologies covered include:

• Advanced sensor development and integration
• Flexible and stretchable electronics
• Printed electronics manufacturing
• Novel materials including conductive inks and polymers
• Battery and energy harvesting innovations
• Display technologies including microLED
• Wireless connectivity solutions

The report profiles >900 companies across the wearable technology value chain, from component manufacturers to end-product developers. It provides detailed analysis of market leaders and innovative startups advancing the field through technological breakthroughs and novel applications. Companies profiled include Abbott Diabetes Care, Artinis Medical Systems, Biobeat Technologies, Biosency, Bosch Sensortec, Cerca Magnetics, Cosinuss, Datwyler, Dexcom, DigiLens, Dispelix, Doublepoint, EarSwitch, Emteq Limited, Epicore Biosystems, Equivital, HTC, IDUN Technologies, IQE, Infi-Tex, Jade Bird Display, Know Labs, Kokoon, Lenovo, LetinAR, Liquid Wire, Lumus, Lynx, Mateligent GmbH, MICLEDI, MICROOLED, Mojo Vision, Nanoleq, Nanusens, NeuroFusion, Oorym, Optinvent, OQmented, Orpyx, Ostendo Technologies, PKVitality, PragmatIC, PROPHESEE, RayNeo (TCL), Raynergy Tek, Rhaeos Inc, Sefar, Segotia, Sony, STMicroelectronics, StretchSense, Tacterion, TDK, Teveri, The Metaverse Standards Forum, TriLite Technologies, TruLife Optics, Valencell, Vitality, VitreaLab, VividQ, Wearable Devices Ltd., WHOOP, Wisear, Withings Health Solutions, XSensio, Zimmer and Peacock and more......

The report also examines:

• Manufacturing processes and challenges
• Material developments and innovations
• Component integration techniques
• Power management solutions
• Data processing and analytics
• Regulatory considerations
• Market barriers and opportunities
• Investment trends and funding

The research highlights emerging applications across multiple sectors:

Healthcare and Medical:

• Remote patient monitoring
• Diagnostic devices
• Drug delivery systems
• Rehabilitation technology
• Mental health applications

Consumer and Fitness:

• Activity tracking
• Sports performance analysis
• Sleep monitoring
• Stress management
• Personal safety

Enterprise and Industrial:

• Workplace safety monitoring
• Industrial training
• Remote assistance
• Productivity enhancement
• Process optimization

Gaming and Entertainment:

• Virtual reality gaming
• Augmented reality experiences
• Mixed reality applications
• Interactive entertainment
• Immersive media

The report analyzes key market trends including:

• Shift toward flexible and stretchable form factors
• Integration of advanced sensing capabilities
• Development of smart textiles and e-fabrics
• Improvements in power efficiency and battery life
• Enhanced data processing and AI integration
• Growth in medical and healthcare applications
• Expansion of AR/VR/MR technology

With over 1000 pages of detailed analysis, including hundreds of figures, tables and company profiles, this report provides essential intelligence for:

• Wearable device manufacturers
• Component suppliers
• Material developers
• Electronics companies
• Healthcare providers
• Investment firms
• Research institutions
• Technology strategists

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Table of Contents

1 EXECUTIVE SUMMARY74

1.1The evolution of electronics 76
1.2The wearables revolution   78
1.3The wearable tech market in 2024   81
1.4Wearable market leaders   83
1.5Continuous monitoring   83
1.6Market map for wearable electronics and sensors   84
1.7From rigid to flexible and stretchable 85
1.8Flexible and stretchable electronics in wearables 86
1.9Stretchable artificial skin   88
1.10 Role in the metaverse   89
1.11 Wearable electronics in the textiles industry89
1.12 New conductive materials91
1.13 Entertainment   94
1.14 Growth in flexible and stretchable electronics market   94
1.14.1 Recent growth in Printed, flexible and stretchable products  94
1.14.2 Future growth 95
1.14.3 Advanced materials as a market driver 95
1.14.4 Growth in remote health monitoring and diagnostics 95
1.15 Innovations at CES 2021-2024  97
1.16 Investment funding and buy-outs 2019-2024  100
1.17 Flexible hybrid electronics (FHE)  104
1.18 Sustainability in flexible electronics   107

 
2 INTRODUCTION  109

2.1Introduction to wearable technology and wearable sensors  109
2.1.1What is wearable technology?   109
2.1.1.1 Wearable sensing   110
2.1.1.1.1   Types   111
2.1.1.1.2   Market trends in wearable sensors 111
2.1.1.1.3   Markets  112
2.2Form factors   113
2.2.1Smart Watches 115
2.2.2Smart Bands  116
2.2.3Smart Glasses  117
2.2.4Smart Clothing 117
2.2.5Smart Patches   118
2.2.6Smart Rings119
2.2.7Hearables120
2.2.8Head-Mounted 120
2.2.9Smart Insoles 122
2.3Wearable sensors   122
2.3.1Motion Sensors122
2.3.1.1 Overview   122
2.3.1.2 Technology and Components 122
2.3.1.2.1   Inertial Measurement Units (IMUs) 122
2.3.1.2.1.1  MEMs accelerometers 123
2.3.1.2.1.2  MEMS Gyroscopes 123
2.3.1.2.1.3  IMUs in smart-watches   123
2.3.1.2.2   Tunneling magnetoresistance sensors (TMR)  124
2.3.1.3 Applications   125
2.3.2Optical Sensors   126
2.3.2.1 Overview   126
2.3.2.2 Technology and Components 126
2.3.2.2.1   Photoplethysmography (PPG) 126
2.3.2.2.2   Spectroscopy 127
2.3.2.2.3   Photodetectors 128
2.3.2.3 Applications   129
2.3.2.3.1   Heart Rate Optical Sensors  129
2.3.2.3.2   Pulse Oximetry Optical Sensors131
2.3.2.3.2.1  Blood oxygen measurement 131
2.3.2.3.2.2  Wellness and Medical Applications131
2.3.2.3.2.3  Consumer Pulse Oximetry131
2.3.2.3.2.4  Pediatric Applications  132
2.3.2.3.2.5  Skin Patches   132
2.3.2.3.3   Blood Pressure Optical Sensors132
2.3.2.3.3.1  Commercialization132
2.3.2.3.3.2  Oscillometric blood pressure measurement133
2.3.2.3.3.3  Combination of PPG and ECG133
2.3.2.3.3.4  Non-invasive Blood Pressure Sensing   133
2.3.2.3.3.5  Blood Pressure Hearables 134
2.3.2.3.4   Non-Invasive Glucose Monitoring Optical Sensors  135
2.3.2.3.4.1  Overview   135
2.3.2.3.4.2  Other Optical Approaches135
2.3.2.3.5   fNIRS Optical Sensors 136
2.3.2.3.5.1  Overview   136
2.3.2.3.5.2  Brain-Computer Interfaces   137
2.3.3Force Sensors   138
2.3.3.1 Overview   138
2.3.3.1.1   Piezoresistive force sensing 138
2.3.3.1.2   Thin film pressure sensors138
2.3.3.2 Technology and Components 139
2.3.3.2.1   Materials   140
2.3.3.2.2   Piezoelectric polymers140
2.3.3.2.3   Temperature sensing and Remote Patient Monitoring (RPM) integration 140
2.3.3.2.4   Wearable force and pressure sensors   141
2.3.4Strain Sensors   141
2.3.4.1 Overview   141
2.3.4.2 Technology and Components 141
2.3.4.3 Applications   141
2.3.4.3.1   Healthcare   142
2.3.4.3.2   Wearable Strain Sensors142
2.3.4.3.3   Temperature Sensors   142
2.3.5Chemical Sensors  144
2.3.5.1 Overview   144
2.3.5.2 Optical Chemical Sensors146
2.3.5.3 Technology and Components 146
2.3.5.3.1   Continuous Glucose Monitoring   146
2.3.5.3.2   Commercial CGM systems  147
2.3.5.4 Applications   148
2.3.5.4.1   Sweat-based glucose monitoring149
2.3.5.4.2   Tear glucose measurement  149
2.3.5.4.3   Salivary glucose monitoring 149
2.3.5.4.4   Breath analysis for glucose monitoring150
2.3.5.4.5   Urine glucose monitoring  150
2.3.6Biosensors  150
2.3.6.1 Overview   150
2.3.6.2 Applications   151
2.3.6.2.1   Wearable Alcohol Sensors151
2.3.6.2.2   Wearable Lactate Sensors151
2.3.6.2.3   Wearable Hydration Sensors   151
2.3.6.2.4   Smart diaper technology152
2.3.6.2.5   Ultrasound technology152
2.3.6.2.6   Microneedle technology for continuous fluid sampling152
2.3.7Quantum Sensors  153
2.3.7.1 Magnetometry  153
2.3.7.2 Tunneling magnetoresistance sensors 155
2.3.7.3 Chip-scale atomic clocks  156
2.3.8Wearable Electrodes 157
2.3.8.1 Overview   157
2.3.8.2 Applications   158
2.3.8.2.1   Skin Patches and E-textiles   159
2.3.8.3 Technology and Components 159
2.3.8.3.1   Electrode Selection   160
2.3.8.3.2   E-textiles   160
2.3.8.3.3   Microneedle electrodes  160
2.3.8.3.4   Electronic Skins   162
2.3.8.4 Applications   163
2.3.8.4.1   Electrocardiogram (ECG) wearable electrodes164
2.3.8.4.2   Electroencephalography (EEG) wearable electrodes represent   165
2.3.8.4.3   Electromyography (EMG) wearable electrodes165
2.3.8.4.4   Bioimpedance wearable electrodes   166

 
3 MANUFACTURING METHODS168

3.1Comparative analysis  168
3.2Printed electronics 169
3.2.1Technology description   169
3.2.2SWOT analysis  170
3.33D electronics   171
3.3.1Technology description   171
3.3.2SWOT analysis  173
3.4Analogue printing174
3.4.1Technology description   174
3.4.2SWOT analysis  176
3.5Digital printing   177
3.5.1Technology description   177
3.5.2SWOT analysis  179
3.6In-mold electronics (IME)  180
3.6.1Technology description   180
3.6.2SWOT analysis  182
3.7Roll-to-roll (R2R) 183
3.7.1Technology description   183
3.7.2SWOT analysis  186

 
4 MATERIALS AND COMPONENTS   187

4.1Component attachment materials  188
4.1.1Conductive adhesives 189
4.1.2Biodegradable adhesives  189
4.1.3Magnets190
4.1.4Bio-based solders  190
4.1.5Bio-derived solders   190
4.1.6Recycled plastics   190
4.1.7Nano adhesives   191
4.1.8Shape memory polymers   191
4.1.9Photo-reversible polymers192
4.1.10 Conductive biopolymers193
4.1.11 Traditional thermal processing methods 193
4.1.12 Low temperature solder  194
4.1.13 Reflow soldering  196
4.1.14 Induction soldering197
4.1.15 UV curing  198
4.1.16 Near-infrared (NIR) radiation curing 198
4.1.17 Photonic sintering/curing   198
4.1.18 Hybrid integration   199
4.2Conductive inks   199
4.2.1Metal-based conductive inks  202
4.2.2Nanoparticle inks   203
4.2.3Silver inks 203
4.2.4Particle-Free conductive ink 204
4.2.5Copper inks204
4.2.6Gold (Au) ink   206
4.2.7Conductive polymer inks   206
4.2.8Liquid metals 207
4.2.9Companies 207
4.3Printable semiconductors 211
4.3.1Technology overview 211
4.3.2Advantages and disadvantages212
4.3.3SWOT analysis  213
4.4Printable sensing materials  214
4.4.1Overview   214
4.4.2Types   214
4.4.3SWOT analysis  216
4.5Flexible Substrates 217
4.5.1Flexible plastic substrates219
4.5.1.1 Types of materials  220
4.5.1.2 Flexible (bio) polyimide PCBs 220
4.5.2Paper substrates 221
4.5.2.1 Overview   221
4.5.3Glass substrates 222
4.5.3.1 Overview   222
4.5.4Textile substrates223
4.6Flexible ICs  223
4.6.1Description 223
4.6.2Flexible metal oxide ICs  224
4.6.3Comparison of flexible integrated circuit technologies  225
4.6.4SWOT analysis  225
4.7Printed PCBs  226
4.7.1Description 226
4.7.2High-Speed PCBs   229
4.7.3Flexible PCBs 229
4.7.43D Printed PCBs  230
4.7.5Sustainable PCBs   231
4.8Thin film batteries   232
4.8.1Technology description   232
4.8.2SWOT analysis  233
4.9Energy harvesting   233
4.9.1Approaches233
4.9.2Perovskite photovoltaics234
4.9.3Applications   235
4.9.4SWOT analysis  235

 
5 CONSUMER ELECTRONICS WEARABLE TECHNOLOGY   237

5.1Market drivers and trends  237
5.2Wearable sensors   240
5.2.1Types   240
5.2.2Wearable sensor technologies   240
5.2.3Opportunities 242
5.2.4Consumer acceptance242
5.2.5Healthcare   242
5.2.6Trends 245
5.3Wearable actuators   248
5.3.1Applications   248
5.3.2Types   249
5.3.3Electrical stimulation technologies 250
5.3.4Regulations 251
5.3.5Batteries252
5.3.6Wireless communication technologies253
5.4Recent market developments 254
5.5Wrist-worn wearables  255
5.5.1Overview   255
5.5.2Recent developments and future outlook  255
5.5.3Wrist-worn sensing technologies 256
5.5.4Activity tracking   257
5.5.5Advanced biometric sensing   257
5.5.5.1 Blood oxygen and respiration rate258
5.5.5.2 Established sensor hardware  259
5.5.5.3 Blood Pressure 259
5.5.5.4 Spectroscopic technologies260
5.5.5.5 Non-Invasive Glucose Monitoring261
5.5.5.6 Minimally invasive glucose monitoring 262
5.5.6Wrist-worn communication technologies  263
5.5.7Luxury and traditional watch industry   264
5.5.8Smart-strap technologies  265
5.5.9Driver monitoring technologies  266
5.5.10 Sports-watches, smart-watches and fitness trackers 267
5.5.10.1Sensing  267
5.5.10.2Actuating  269
5.5.10.3SWOT analysis  273
5.5.11 Health monitoring  274
5.5.12 Energy harvesting for powering smartwatches276
5.5.13 Main producers and products276
5.6Sports and fitness  278
5.6.1Overview   278
5.6.2Wearable devices and apparel   278
5.6.3Skin patches   278
5.6.4Products   280
5.7Hearables282
5.7.1Hearing assistance technologies 285
5.7.1.1 Products   287
5.7.2Technology advancements   288
5.7.3Assistive Hearables   289
5.7.3.1 Biometric Monitoring 289
5.7.4SWOT analysis  291
5.7.5Health & Fitness Hearables  291
5.7.6Multimedia Hearables 292
5.7.7Artificial Intelligence (AI)292
5.7.8Biometric Monitoring 292
5.7.8.1 Sensors 292
5.7.8.2 Heart Rate Monitoring in Sports Headphones  295
5.7.8.3 Integration into hearing assistance 295
5.7.8.4 Advanced Sensing Technologies   296
5.7.8.5 Blood pressure hearables 296
5.7.8.6 Sleep monitoring market297
5.7.9Companies and products  299
5.8Sleep trackers and wearable monitors 300
5.8.1Built in function in smart watches and fitness trackers  301
5.8.2Smart rings  302
5.8.3Headbands 303
5.8.4Sleep monitoring devices   305
5.8.4.1 Companies and products  307
5.9Pet and animal wearables 308
5.10 Military wearables  312
5.11 Industrial and workplace monitoring 312
5.11.1 Products   313
5.12 Global market forecasts 315
5.12.1 Volume  315
5.12.2 Revenues  317
5.13 Market challenges  319
5.14 Company profiles   320 (123 company profiles)

 
6 MEDICAL AND HEALTHCARE WEARABLE TECHNOLOGY 399

6.1Market drivers399
6.2Current state of the art401
6.2.1Wearables for Digital Health401
6.2.2Wearable medical device products 402
6.2.3Temperature and respiratory rate monitoring   404
6.3Wearable and health monitoring and rehabilitation 405
6.3.1Market overview   405
6.3.2Companies and products  406
6.4Electronic skin patches   411
6.4.1Electrochemical biosensors412
6.4.2Printed pH sensors413
6.4.3Printed batteries  414
6.4.4Materials   415
6.4.4.1 Summary of advanced materials  415
6.4.5Temperature and respiratory rate monitoring   416
6.4.5.1 Market overview   416
6.4.5.2 Companies and products  417
6.4.6Continuous glucose monitoring (CGM)419
6.4.6.1 Market overview   419
6.4.7Minimally-invasive CGM sensors 419
6.4.7.1 Technologies  420
6.4.8Non-invasive CGM sensors  422
6.4.8.1 Commercial devices 422
6.4.8.2 Companies and products  424
6.4.9Cardiovascular monitoring   426
6.4.9.1 Market overview   426
6.4.9.2 ECG sensors  427
6.4.9.2.1   Companies and products  427
6.4.9.3 PPG sensors   430
6.4.9.3.1   Companies and products  430
6.4.10 Pregnancy and newborn monitoring  431
6.4.10.1Market overview   431
6.4.10.2Companies and products  431
6.4.11 Hydration sensors  433
6.4.11.1Market overview   433
6.4.11.2Companies and products  433
6.4.12 Wearable sweat sensors (medical and sports)435
6.4.12.1Market overview   435
6.4.12.2Companies and products  437
6.5Wearable drug delivery438
6.5.1Companies and products  439
6.6Cosmetics patches441
6.6.1Companies and products  442
6.7Femtech devices 443
6.7.1Companies and products  444
6.8Smart footwear for health monitoring   446
6.8.1Companies and products  447
6.9Smart contact lenses and smart glasses for visually impaired 448
6.9.1Companies and products  448
6.10 Smart woundcare   449
6.10.1 Companies and products  451
6.11 Smart diapers452
6.11.1 Companies and products  452
6.12 Wearable robotics-exo-skeletons, bionic prostheses, exo-suits, and body worn collaborative robots 453
6.12.1 Companies and products  454
6.13 Global market forecasts 472
6.13.1 Volume  472
6.13.2 Revenues  474
6.14 Market challenges  475
6.15 Company profiles   477 (331 company profiles)

 
7 GAMING AND ENTERTAINMENT WEARABLE TECHNOLOGY (VR/AR/MR)  692

7.1Introduction692
7.2Classification of VR, AR, MR, and XR 693
7.2.1XR controllers and sensing systems   695
7.2.2XR positional and motion tracking systems   695
7.2.3Wearable technology for XR 697
7.2.4Wearable Gesture Sensors for XR698
7.2.5Edge Sensing and AI  698
7.2.6VR Technology   698
7.2.6.1 Overview   698
7.2.6.2 VR Headset Types   699
7.2.6.3 Future outlook for VR technology 699
7.2.6.4 VR Lens Technology   700
7.2.6.5 VR challenges700
7.2.6.6 Market growth   700
7.2.7AR Technology   701
7.2.7.1 Overview   701
7.2.7.2 AR and MR distinction 701
7.2.7.3 AR for Assistive Technology  701
7.2.7.4 Consumer AR market   702
7.2.7.5 Optics Technology for AR and VR  706
7.2.7.5.1   Optical Combiners708
7.2.7.6 AR display technology  708
7.2.7.7 Challenges  709
7.2.8Metaverse 709
7.2.9Mixed Reality (MR) smart glasses 710
7.2.10 OLED microdisplays 711
7.2.10.1MiniLED 711
7.2.10.1.1High dynamic range miniLED displays  713
7.2.10.1.2Quantum dot films for miniLED displays 714
7.2.10.2MicroLED  715
7.2.10.2.1Integration   717
7.2.10.2.2Transfer technologies   718
7.2.10.2.3MicroLED display specifications   722
7.2.10.2.4Advantages 722
7.2.10.2.5Transparency 724
7.2.10.2.6Costs  725
7.2.10.2.7MicroLED contact lenses   725
7.2.10.2.8Products   726
7.2.10.2.9VR and AR MicroLEDs  726
7.3Global market forecasts 727
7.3.1Volume  727
7.3.2Revenues  728
7.4Company profiles   730 (96 company profiles)

 
8 ELECTRONIC TEXTILES (E-TEXTILES) AND SMART APPAREL   796

8.1Macro-trends 796
8.2Market drivers797
8.3SWOT analysis  799
8.4Performance requirements for E-textiles 800
8.5Growth prospects for electronic textiles  801
8.6Textiles in the Internet of Things804
8.7Types of E-Textile products   806
8.7.1Embedded e-textiles 807
8.7.2Laminated e-textiles  808
8.8Materials and components  808
8.8.1Integrating electronics for E-Textiles   808
8.8.1.1 Textile-adapted 810
8.8.1.2 Textile-integrated 810
8.8.1.3 Textile-based  810
8.8.2Manufacturing of E-textiles   810
8.8.2.1 Integration of conductive polymers and inks811
8.8.2.2 Integration of conductive yarns and conductive filament fibers   812
8.8.2.3 Integration of conductive sheets   813
8.8.3Flexible and stretchable electronics   813
8.8.4E-textiles materials and components816
8.8.4.1 Conductive and stretchable fibers and yarns   817
8.8.4.1.1   Production   820
8.8.4.1.2   Metals 820
8.8.4.1.3   Carbon materials and nanofibers821
8.8.4.1.3.1  Graphene 823
8.8.4.1.3.2  Carbon nanotubes 824
8.8.4.1.3.3  Nanofibers  826
8.8.4.2 Mxenes  827
8.8.4.3 Hexagonal boron-nitride (h-BN)/Bboron nitride nanosheets (BNNSs) 828
8.8.4.4 Conductive polymers   830
8.8.4.4.1   PDMS  833
8.8.4.4.2   PEDOT: PSS 833
8.8.4.4.3   Polypyrrole (PPy)  833
8.8.4.4.4   Conductive polymer composites 834
8.8.4.4.5   Ionic conductive polymers834
8.8.4.5 Conductive inks   834
8.8.4.5.1   Aqueous-Based Ink   836
8.8.4.5.2   Solvent-Based Ink  837
8.8.4.5.3   Oil-Based Ink 837
8.8.4.5.4   Hot-Melt Ink838
8.8.4.5.5   UV-Curable Ink 838
8.8.4.5.6   Metal-based conductive inks  839
8.8.4.5.6.1  Nanoparticle ink  840
8.8.4.5.6.2  Silver inks 840
8.8.4.5.6.2.1  Silver flake   841
8.8.4.5.6.2.2  Silver nanoparticle ink 841
8.8.4.5.6.2.3  Formulation842
8.8.4.5.6.2.4  Conductivity   843
8.8.4.5.6.2.5  Particle-Free silver conductive ink   843
8.8.4.5.6.3  Copper inks844
8.8.4.5.6.3.1  Properties 844
8.8.4.5.6.3.2  Silver-coated copper 845
8.8.4.5.6.4  Gold (Au) ink   846
8.8.4.5.6.4.1  Properties 846
8.8.4.5.7   Carbon-based conductive inks 846
8.8.4.5.7.1  Carbon nanotubes 846
8.8.4.5.7.2  Single-walled carbon nanotubes  848
8.8.4.5.7.3  Graphene 849
8.8.4.5.8   Liquid metals 853
8.8.4.5.8.1  Properties 853
8.8.4.6 Electronic filaments  854
8.8.4.7 Phase change materials 854
8.8.4.7.1   Temperature controlled fabrics 854
8.8.4.8 Shape memory materials  855
8.8.4.9 Metal halide perovskites857
8.8.4.10Nanocoatings in smart textiles   857
8.8.4.113D printing   860
8.8.4.11.1Fused Deposition Modeling (FDM)  860
8.8.4.11.2Selective Laser Sintering (SLS)   860
8.8.4.11.3Products   861
8.8.5E-textiles components862
8.8.5.1 Sensors and actuators862
8.8.5.1.1   Physiological sensors  863
8.8.5.1.2   Environmental sensors   864
8.8.5.1.3   Pressure sensors 864
8.8.5.1.3.1  Flexible capacitive sensors  864
8.8.5.1.3.2  Flexible piezoresistive sensors   864
8.8.5.1.3.3  Flexible piezoelectric sensors865
8.8.5.1.4   Activity sensors865
8.8.5.1.5   Strain sensors   866
8.8.5.1.5.1  Resistive sensors866
8.8.5.1.5.2  Capacitive strain sensors  867
8.8.5.1.6   Temperature sensors867
8.8.5.1.7   Inertial measurement units (IMUs)  867
8.8.5.2 Electrodes867
8.8.5.3 Connectors 868
8.9Applications, markets and products  868
8.9.1Current E-textiles and smart clothing products  869
8.9.2Temperature monitoring and regulation   870
8.9.2.1 Heated clothing   870
8.9.2.2 Heated gloves   872
8.9.2.3 Heated insoles 873
8.9.2.4 Heated jacket and clothing products 874
8.9.2.5 Materials used in flexible heaters and applications 875
8.9.3Stretchable E-fabrics876
8.9.4Therapeutic products   876
8.9.5Sport & fitness  877
8.9.5.1 Products   880
8.9.6Smart footwear 882
8.9.6.1 Companies and products  883
8.9.7Wearable displays  884
8.9.8Military   886
8.9.9Textile-based lighting887
8.9.9.1 OLEDs 887
8.9.10 Smart gloves  887
8.9.11 Powering E-textiles 888
8.9.11.1Advantages and disadvantages of main battery types for E-textiles  890
8.9.11.2Bio-batteries   891
8.9.11.3Challenges for battery integration in smart textiles   891
8.9.11.4Textile supercapacitors   892
8.9.11.5Energy harvesting   893
8.9.11.5.1Photovoltaic solar textiles 894
8.9.11.5.2Energy harvesting nanogenerators  896
8.9.11.5.2.1   TENGs 896
8.9.11.5.2.2   PENGs897
8.9.11.5.3Radio frequency (RF) energy harvesting   897
8.9.12 Motion capture for AR/VR  897
8.10 Global market forecasts 899
8.10.1 Volume  899
8.10.2 Revenues  900
8.11 Market challenges  902
8.12 Company profiles   904 (152 company profiles)

 
9 ENERGY STORAGE AND HARVESTING FOR WEARABLE TECHNOLOGY 1007

9.1Macro-trends 1007
9.2Market drivers1008
9.3SWOT analysis  1008
9.4Battery Development1009
9.4.1Enhanced Energy Density and Performance 1011
9.4.2Stretchable Batteries1011
9.4.3Textile-Based Batteries1012
9.4.4Printable Batteries  1012
9.4.5Sustainable and Biodegradable Batteries   1013
9.4.6Self-Healing Batteries  1013
9.4.7Solid-State Flexible Batteries  1014
9.4.8Integration with Energy Harvesting  1014
9.4.9Nanostructured Materials 1014
9.4.10 Thin-Film Battery Technologies  1015
9.5Applications of printed and flexible electronics  1016
9.6Flexible and stretchable batteries for electronics  1016
9.7Approaches to flexibility 1018
9.8Flexible Battery Technologies  1022
9.8.1Thin-film Lithium-ion Batteries   1022
9.8.1.1 Types of Flexible/stretchable LIBs1025
9.8.1.1.1   Flexible planar LiBs   1025
9.8.1.1.2   Flexible Fiber LiBs   1026
9.8.1.1.3   Flexible micro-LiBs1026
9.8.1.1.4   Stretchable lithium-ion batteries  1028
9.8.1.1.5   Origami and kirigami lithium-ion batteries  1029
9.8.1.2 Flexible Li/S batteries1030
9.8.1.3 Flexible lithium-manganese dioxide (Li?MnO2) batteries 1031
9.8.2Printed Batteries  1032
9.8.2.1 Technical specifications 1032
9.8.2.2 Components  1033
9.8.2.3 Design 1034
9.8.2.4 Key features1035
9.8.2.4.1   Printable current collectors  1036
9.8.2.4.2   Printable electrodes  1036
9.8.2.4.3   Materials   1037
9.8.2.4.4   Applications   1038
9.8.2.4.5   Printing techniques1039
9.8.2.4.6   Lithium-ion (LIB) printed batteries1041
9.8.2.4.7   Zinc-based printed batteries1043
9.8.2.4.8   3D Printed batteries   1046
9.8.2.5 3D Printing techniques for battery manufacturing 1048
9.8.2.5.1.1  Materials for 3D printed batteries 1049
9.8.3Thin-Film Solid-state Batteries   1050
9.8.3.1 Solid-state electrolytes1051
9.8.3.2 Features and advantages  1053
9.8.3.3 Technical specifications 1054
9.8.3.4 Microbatteries   1058
9.8.3.4.1   Introduction1058
9.8.3.4.2   3D designs  1060
9.8.4Stretchable Batteries1060
9.8.5Other Emerging Technologies 1061
9.8.5.1 Metal-sulfur batteries   1061
9.8.5.2 Flexible zinc-based batteries   1062
9.8.5.3 Flexible silver?zinc (Ag?Zn) batteries  1063
9.8.5.4 Flexible Zn?Air batteries  1063
9.8.5.5 Flexible zinc-vanadium batteries  1064
9.8.5.6 Fiber-shaped batteries 1064
9.8.5.6.1   Carbon nanotubes 1065
9.8.5.6.2   Applications   1066
9.8.5.6.3   Challenges  1067
9.8.5.7 Transparent batteries1067
9.8.5.7.1   Components  1068
9.8.5.8 Degradable batteries1069
9.8.5.8.1   Components  1070
9.8.5.9 Fiber-shaped batteries 1071
9.8.5.9.1   Carbon nanotubes 1071
9.8.5.9.2   Types   1072
9.8.5.9.3   Applications   1073
9.8.5.9.4   Challenges  1073
9.9Key Components of Flexible Batteries   1074
9.9.1Electrodes1074
9.9.1.1 Cable-type batteries 1075
9.9.1.2 Batteries-on-wire1076
9.9.2Electrolytes 1076
9.9.3Separators   1082
9.9.4Current Collectors  1083
9.9.4.1 Carbon Materials for Current Collectors in Flexible Batteries1084
9.9.5Packaging1085
9.9.5.1 Lithium-Polymer Pouch Cells  1085
9.9.5.2 Flexible Pouch Cells  1087
9.9.5.3 Encapsulation Materials 1088
9.9.6Other Manufacturing Techniques 1089
9.10 Performance Metrics and Characteristics  1090
9.10.1 Energy Density  1090
9.10.2 Power Density   1090
9.10.3 Cycle Life  1091
9.10.4 Flexibility and Bendability 1091
9.11 Printed supercapacitors 1092
9.11.1 Electrode materials   1093
9.11.2 Electrolytes 1094
9.12 Photovoltaics 1098
9.12.1 Conductive pastes 1098
9.12.2 Organic photovoltaics (OPV)   1099
9.12.3 Perovskite PV 1099
9.12.4 Flexible and stretchable photovoltaics1099
9.12.4.1Companies 1100
9.12.5 Photovoltaic solar textiles 1100
9.12.6 Solar tape 1102
9.12.7 Origami-like solar cells 1102
9.12.8 Spray-on and stick-on perovskite photovoltaics1103
9.12.9 Photovoltaic solar textiles 1103
9.13 Transparent and flexible heaters   1104
9.13.1 Technology overview 1104
9.13.2 Applications   1105
9.13.2.1Automotive Industry  1105
9.13.2.1.1Defrosting and Defogging Systems  1106
9.13.2.1.2Heated Windshields and Mirrors  1107
9.13.2.1.3Touch Panels and Displays   1108
9.13.2.2Aerospace and Aviation  1109
9.13.2.2.1Aircraft Windows and Canopies1109
9.13.2.2.2Sensor and Camera Housings1109
9.13.2.3Consumer Electronics 1109
9.13.2.3.1Smartphones and Tablets  1109
9.13.2.3.2Wearable Devices   1109
9.13.2.3.3Smart Home Appliances1109
9.13.2.4Building and Architecture  1110
9.13.2.4.1Smart Windows1110
9.13.2.4.2Heated Glass Facades1111
9.13.2.4.3Greenhouse and Skylight Applications 1111
9.13.2.5Medical and Healthcare 1112
9.13.2.5.1Incubators and Warming Beds   1112
9.13.2.5.2Surgical Microscopes and Endoscopes   1113
9.13.2.5.3Medical Imaging Equipment 1113
9.13.2.6Display Technologies1114
9.13.2.6.1LCD Displays 1114
9.13.2.6.2OLED Displays  1114
9.13.2.6.3Flexible and Transparent Displays   1115
9.13.2.7Energy Systems1116
9.13.2.7.1Solar Panels (De-icing and Efficiency Enhancement) 1116
9.13.2.7.2Fuel Cells 1116
9.13.2.7.3Battery Systems   1117
9.14 Thermoelectric energy harvesting   1118
9.15 Market challenges  1119
9.16 Global market forecasts 1119
9.16.1 Volume  1119
9.16.2 Revenues  1120
9.17 Companies 1123 (60 company profiles)

 
10  RESEARCH METHODOLOGY  1167

 
11  REFERENCES 1168

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List of Tables/Graphs

List of Tables

• Table 1. Types of wearable devices and applications. 79
• Table 2. Types of wearable devices and the data collected. 81
• Table 3. Main Wearable Device Companies by Shipment Volume, Market Share, and Year-Over-Year Growth, (million units). 82
• Table 4. New wearable tech products 2022-2024. 82
• Table 5. Wearable market leaders by market segment. 83
• Table 6. Applications in printed, flexible and stretchable electronics, by advanced materials type and benefits thereof. 87
• Table 7. Advanced materials for Printed, flexible and stretchable sensors and Electronics-Advantages and disadvantages. 92
• Table 8. Sheet resistance (RS) and transparency (T) values for transparent conductive oxides and alternative materials for transparent conductive electrodes (TCE). 93
• Table 9. Wearable electronics at CES 2021-2024. 97
• Table 10. Wearables Investment funding and buy-outs 2019-2024. 100
• Table 11. Comparative analysis of conventional and flexible hybrid electronics. 104
• Table 12. Materials, components, and manufacturing methods for FHE 105
• Table 13. Research and commercial activity in FHE. 106
• Table 14. Value proposition of wearable sensors versus non wearable alternatives. 110
• Table 15. Overview of Wearable Sensor Types. 111
• Table 16. Market Drivers in the Wearable Sensor Market. 112
• Table 17. Markets for Wearable Sensors. 112
• Table 18. Wearable Electronic Form Factors. 114
• Table 19. Trends in Wearable Sensor Innovations by Form-Factor: 115
• Table 20. Applications and Opportunities for TMRs in Wearables. 125
• Table 21. Wearable Motion Sensors Applications. 125
• Table 22. Applications of Photoplethysmography (PPG). 127
• Table 23. Wearable Brands in Cardiovascular Clinical Research. 132
• Table 24. Technologies for Cuff-less Blood Pressure. 134
• Table 25. Market outlook for Wearable Blood Pressure Devices. 134
• Table 26. Non-invasive glucose monitoring. 136
• Table 27. fNIRS Companies. 136
• Table 28. Comparing fNIRS to Other Non-invasive Brain Imaging Methods. 137
• Table 29. Thin Film Pressure Sensor Architectures. 139
• Table 30. Applications of Printed Force Sensors. 139
• Table 31. Companies in Printed Strain Sensors. 142
• Table 32. Types of Temperature Sensor. 143
• Table 33. Technology Readiness Level for strain sensors. 144
• Table 34. Commercial CGM Devices. 148
• Table 35. Applications of Wearable Chemical Sensors. 150
• Table 36. Market Outlook of Wearable Sensors for Novel Biometrics. 153
• Table 37. Applications of Wearable OPMs – MEG. 154
• Table 38. Applications and Market Opportunities for TMRs. 155
• Table 39. Wearable Electrode Types. 158
• Table 40. Applications of wearable electrodes. 158
• Table 41. Printed Electrodes for Skin Patches and E-textiles. 159
• Table 42. Companies in Wearable Electrodes. 160
• Table 43. Materials and Manufacturing Approaches for Electronic Skins. 162
• Table 44. Wearable electrodes Applications. 163
• Table 45. Manufacturing Methods for Wearable Electronics. 168
• Table 46. Manufacturing methods for printed, flexible and hybrid electronics. 169
• Table 47. Common printing methods used in printed electronics manufacturing in terms of resolution vs throughput. 169
• Table 48. Manufacturing methods for 3D electronics. 171
• Table 49. Readiness level of various additive manufacturing technologies for electronics applications. 172
• Table 50. Fully 3D printed electronics process steps 173
• Table 51. Manufacturing methods for Analogue manufacturing. 174
• Table 52. Technological and commercial readiness level of analogue printing methods. 176
• Table 53. Manufacturing methods for Digital printing 177
• Table 54. Innovations in high resolution printing. 178
• Table 55. Key manufacturing methods for creating smart surfaces with integrated electronics. 181
• Table 56. IME manufacturing techniques. 182
• Table 57. Applications of R2R electronics manufacturing. 184
• Table 58. Technology readiness level for R2R manufacturing. 185
• Table 59. Materials for wearable electronics and sensors. 187
• Table 60. Comparison of component attachment materials. 188
• Table 61. Comparison between sustainable and conventional component attachment materials for printed circuit boards 189
• Table 62. Comparison between the SMAs and SMPs. 191
• Table 63. Comparison of conductive biopolymers versus conventional materials for printed circuit board fabrication. 193
• Table 64. Low temperature solder alloys. 194
• Table 65. Thermally sensitive substrate materials. 195
• Table 66. Typical conductive ink formulation. 200
• Table 67. Comparative properties of conductive inks. 202
• Table 68. Comparison of the electrical conductivities of liquid metal with typical conductive inks. 207
• Table 69. Conductive ink producers. 207
• Table 70. Technology readiness level of printed semiconductors. 212
• Table 71. Organic semiconductors: Advantages and disadvantages. 212
• Table 72. Market Drivers for printed/flexible sensors. 214
• Table 73. Overview of specific printed/flexible sensor types. 214
• Table 74. Properties of typical flexible substrates. 217
• Table 75. Comparison of stretchable substrates. 218
• Table 76. Main types of materials used as flexible plastic substrates in flexible electronics. 220
• Table 77. Applications of flexible (bio) polyimide PCBs. 221
• Table 78. Paper substrates: Advantages and disadvantages. 222
• Table 79. Comparison of flexible integrated circuit technologies. 225
• Table 80. PCB manufacturing process. 228
• Table 81. Challenges in PCB manufacturing. 228
• Table 82. 3D PCB manufacturing. 231
• Table 83. Market drivers and trends in wearable electronics. 237
• Table 84. Types of wearable sensors. 240
• Table 85. Opportunities and challenges for the wearable technology industry. 242
• Table 86. Drivers for Wearable Adoption and Innovation. 243
• Table 87. Future Trends in Wearable Technology. 245
• Table 88. Applications of Neuromuscular Electrical Stimulation (NMES) and Electrical Muscle Stimulation (EMS). 251
• Table 89. Wearable batteries, displays and communication systems. 252
• Table 90. Different sensing modalities that can be incorporated into wrist-worn wearable device. 268
• Table 91. Overview of actuating at the wrist 269
• Table 92. Key players in Wrist-Worn Technology. 271
• Table 93. Wearable health monitors. 275
• Table 94. Sports-watches, smart-watches and fitness trackers producers and products. 276
• Table 95. Wearable sensors for sports performance. 279
• Table 96. Wearable sensor products for monitoring sport performance. 280
• Table 97. Product types in the hearing assistance technology market. 282
• Table 98. Audio and Hearing Assistance for Hearables. 284
• Table 99. Hearing Assistance Technologies. 285
• Table 100. Hearing Assistance Technology Products. 287
• Table 101. Sensing options in the ear. 290
• Table 102. Sensing Options in the Ear. 293
• Table 103. Advantages and Limitations for Blood Pressure Hearables. 296
• Table 104. Companies and products in hearables. 299
• Table 105. Example wearable sleep tracker products and prices. 300
• Table 106. Smart ring products. 302
• Table 107. Sleep headband products. 303
• Table 108. Sleep Headband Wearables. 305
• Table 109. Wearable electronics sleep monitoring products. 307
• Table 110. Pet and animal wearable electronics & sensors companies and products. 309
• Table 111. Wearable electronics applications in the military. 312
• Table 112. Industrial Wearable Electronics Product Table 313
• Table 113. Global market for wearable consumer electronics 2020-2035 by type (Millions Units). 315
• Table 114. Global market revenues for wearable consumer electronics, 2018-2035, (millions USD). 317
• Table 115. Market challenges in consumer wearable electronics. 319
• Table 116. Market drivers for printed, flexible and stretchable medical and healthcare sensors and wearables. 399
• Table 117. Examples of wearable medical device products. 402
• Table 118. Medical wearable companies applying products to COVID-19 monitoring and analysis. 405
• Table 119. Applications in flexible and stretchable health monitors, by advanced materials type and benefits thereof. 415
• Table 120. Medical wearable companies applying products to temperate and respiratory monitoring and analysis. 418
• Table 121. Technologies for minimally-invasive and non-invasive glucose detection-advantages and disadvantages. 420
• Table 122. Commercial devices for non-invasive glucose monitoring not released or withdrawn from market. 422
• Table 123. Minimally-invasive and non-invasive glucose monitoring products. 424
• Table 124. ECG Patch Monitor and Clothing Products. 429
• Table 125. PPG Wearable Electronics Companies and Products. 430
• Table 126. Pregnancy and Newborn Monitoring Wearables. 432
• Table 127. Companies developing wearable swear sensors. 437
• Table 128. Wearable electronics drug delivery companies and products. 439
• Table 129. Companies and products, cosmetics and drug delivery patches. 442
• Table 130. Femtech Wearable Electronics. 443
• Table 131. Companies developing femtech wearable technology. 444
• Table 132. Companies and products in smart foowtear and insolves. 447
• Table 133. Companies and products in smart contact lenses. 448
• Table 134. Companies and products in smart wound care. 451
• Table 135. Companies developing smart diaper products. 452
• Table 136. Companies developing wearable robotics. 454
• Table 137. Global Market for Wearable Medical & Healthcare Electronics 2020-2035 (Million Units). 472
• Table 138. Global market for Wearable medical & healthcare electronics, 2020-2035, millions of US dollars. 475
• Table 139. Market challenges in medical and healthcare sensors and wearables. 475
• Table 140. VR and AR Headset Classification. 693
• Table 141. Applications of VR and AR Technology. 694
• Table 142. XR Headset OEM Comparison. 696
• Table 143. Timeline of Modern VR. 698
• Table 144. VR Headset Types. 699
• Table 145. AR Outlook by Device Type 702
• Table 146. AR Outlook by Computing Type. 702
• Table 147. Augmented reality (AR) smart glass products. 703
• Table 148. Mixed Reality (MR) smart glass products. 710
• Table 149. Comparison between miniLED displays and other display types. 711
• Table 150. Comparison of AR Display Light Engines. 715
• Table 151. Comparison to conventional LEDs. 716
• Table 152. Types of microLED. 716
• Table 153. Summary of monolithic integration, monolithic hybrid integration (flip-chip/wafer bonding), and mass transfer technologies. 717
• Table 154. Summary of different mass transfer technologies. 719
• Table 155. Comparison to LCD and OLED. 721
• Table 156. Schematic comparison to LCD and OLED. 722
• Table 157. Commercially available microLED products and specifications. 722
• Table 158. microLED-based display advantages and disadvantages. 723
• Table 159. MicroLED based smart glass products. 726
• Table 160. VR and AR MicroLED products. 726
• Table 161. Global market for gaming and entertainment wearable technology, 2020-2035 (Million Units). 727
• Table 162. Global market for gaming and entertainment wearable technology, 2020-2035, millions of US dollars. 728
• Table 163. Macro-trends for electronic textiles. 796
• Table 164. Market drivers for printed, flexible, stretchable and organic electronic textiles. 797
• Table 165. Examples of smart textile products. 799
• Table 166. Performance requirements for E-textiles. 800
• Table 167. Commercially available smart clothing products. 806
• Table 168. Types of smart textiles. 809
• Table 169. Comparison of E-textile fabrication methods. 810
• Table 170. Types of fabrics for the application of electronic textiles. 811
• Table 171. Methods for integrating conductive compounds. 811
• Table 172. Methods for integrating conductive yarn and conductive filament fiber. 813
• Table 173. 1D electronic fibers including the conductive materials, fabrication strategies, electrical conductivity, stretchability, and applications. 816
• Table 174. Conductive materials used in smart textiles, their electrical conductivity and percolation threshold. 820
• Table 175. Metal coated fibers and their mechanisms. 821
• Table 176. Applications of carbon nanomaterials and other nanomaterials in e-textiles. 822
• Table 177. Applications and benefits of graphene in textiles and apparel. 823
• Table 178. Properties of CNTs and comparable materials. 824
• Table 179. Properties of hexagonal boron nitride (h-BN). 830
• Table 180. Types of flexible conductive polymers, properties and applications. 831
• Table 181. Typical conductive ink formulation. 835
• Table 182. Comparative properties of conductive inks. 835
• Table 183. Comparison of pros and cons of various types of conductive ink compositions. 838
• Table 184: Properties of CNTs and comparable materials. 847
• Table 185. Properties of graphene. 850
• Table 186. Electrical conductivity of different types of graphene. 852
• Table 187. Comparison of the electrical conductivities of liquid metal with typical conductive inks. 853
• Table 188. Nanocoatings applied in the smart textiles industry-type of coating, nanomaterials utilized, benefits and applications. 858
• Table 189. 3D printed shoes. 861
• Table 190. Sensors used in electronic textiles. 862
• Table 191. Features of flexible strain sensors with different structures. 866
• Table 192. Features of resistive and capacitive strain sensors. 867
• Table 193. Typical applications and markets for e-textiles. 868
• Table 194. Commercially available E-textiles and smart clothing products. 869
• Table 195. Example heated jacket products. 871
• Table 196. Heated Gloves Products 872
• Table 197. Heated Insoles Products 873
• Table 198. Heated jacket and clothing products. 874
• Table 199. Examples of materials used in flexible heaters and applications. 875
• Table 200. Wearable Electronic Therapeutics Products. 877
• Table 201. Smart Textiles/E-Textiles for Healthcare and Fitness. 879
• Table 202. Example wearable sensor products for monitoring sport performance. 880
• Table 203.Companies and products in smart footwear. 883
• Table 204. Commercial Applications of Wearable Displays 884
• Table 205. Applications of Wearable Displays. 885
• Table 206. Wearable Electronics Applications in Military. 887
• Table 207. Smart Gloves Companies and Products. 888
• Table 208. Types of Power Supplies for Electronic Textiles. 889
• Table 209. Advantages and disadvantages of batteries for E-textiles. 890
• Table 210. Comparison of prototype batteries (flexible, textile, and other) in terms of area-specific performance. 892
• Table 211. Advantages and disadvantages of photovoltaic, piezoelectric, triboelectric, and thermoelectric energy harvesting in of e-textiles. 893
• Table 212. Teslasuit. 899
• Table 213. Global market for printed and flexible E-textiles and smart apparel electronics, 2020-2035 (Million Units). 899
• Table 214. Global market for printed and flexible E-textiles and smart apparel electronics, 2020-2035, millions of US dollars. 900
• Table 215. Market and technical challenges for E-textiles and smart clothing. 902
• Table 216. Macro-trends in energy vstorage and harvesting for wearables. 1007
• Table 217. Market drivers for Printed and flexible electronic energy storage, generation and harvesting. 1008
• Table 218. Energy applications for printed/flexible electronics. 1016
• Table 219. Comparison of Flexible and Traditional Lithium-Ion Batteries 1019
• Table 220. Material Choices for Flexible Battery Components. 1019
• Table 221. Flexible Li-ion battery products 1023
• Table 222. Thin film vs bulk solid-state batteries. 1024
• Table 223. Summary of fiber-shaped lithium-ion batteries. 1027
• Table 224. Main components and properties of different printed battery types. 1034
• Table 225, Types of printable current collectors and the materials commonly used. 1036
• Table 226. Applications of printed batteries and their physical and electrochemical requirements. 1038
• Table 227. 2D and 3D printing techniques. 1039
• Table 228. Printing techniques applied to printed batteries. 1041
• Table 229. Main components and corresponding electrochemical values of lithium-ion printed batteries. 1041
• Table 230. Printing technique, main components and corresponding electrochemical values of printed batteries based on Zn–MnO2 and other battery types. 1043
• Table 231. Main 3D Printing techniques for battery manufacturing. 1048
• Table 232. Electrode Materials for 3D Printed Batteries. 1049
• Table 233. Main Fabrication Techniques for Thin-Film Batteries. 1050
• Table 234. Types of solid-state electrolytes. 1051
• Table 235. Market segmentation and status for solid-state batteries. 1052
• Table 236. Typical process chains for manufacturing key components and assembly of solid-state batteries. 1053
• Table 237. Comparison between liquid and solid-state batteries. 1058
• Table 238. Types of fiber-shaped batteries. 1065
• Table 239. Components of transparent batteries. 1068
• Table 240. Components of degradable batteries. 1070
• Table 241. Types of fiber-shaped batteries. 1072
• Table 242. Organic vs. Inorganic Solid-State Electrolytes. 1078
• Table 243. Electrode designs in flexible lithium-ion batteries. 1079
• Table 244. Packaging Procedures for Pouch Cells. 1086
• Table 245. Performance Metrics and Characteristics for Printed and Flexible Batteries. 1090
• Table 246. Methods for printing supercapacitors. 1093
• Table 247. Electrode Materials for printed supercapacitors. 1093
• Table 248. Electrolytes for printed supercapacitors. 1095
• Table 249. Main properties and components of printed supercapacitors. 1095
• Table 250. Conductive pastes for photovoltaics. 1098
• Table 251. Companies commercializing thin film flexible photovoltaics. 1100
• Table 252. Examples of materials used in flexible heaters and applications. 1104
• Table 253. Transparent heaters for exterior lighting / sensors / windows. 1105
• Table 254. Types of transparent heaters for automotive exterior applications. 1105
• Table 255. Smart Window Applications of Transparent Heaters. 1110
• Table 256. Applications of Printed and Flexible Fuel Cells. 1117
• Table 257. Market challenges in printed and flexible electronics for energy. 1119
• Table 258. Global market for printed and flexible energy storage, generation and harvesting electronics, 2020-2035 by type (Volume). 1119
• Table 259. Global market for printed and flexible energy storage, generation and harvesting electronics, 2020-2035, millions of US dollars. 1121
• Table 260. 3DOM separator. 1124
• Table 261. Battery performance test specifications of J. Flex batteries. 1146

List of Figures

• Figure 1. Examples of flexible electronics devices. 75
• Figure 2. Evolution of electronics. 76
• Figure 3. Wearable technology inventions. 78
• Figure 4. Market map for wearable electronics and sensors. 84
• Figure 5. Wove Band. 85
• Figure 6. Wearable graphene medical sensor. 86
• Figure 7. Stretchable transistor. 87
• Figure 8. Artificial skin prototype for gesture recognition. 89
• Figure 9. Applications of wearable flexible sensors worn on various body parts. 90
• Figure 10. Systemization of wearable electronic systems. 91
• Figure 11. Baby Monitor. 96
• Figure 12. Wearable health monitor incorporating graphene photodetectors. 96
• Figure 13. LG 77” transparent 4K OLED TV. 98
• Figure 14. 137-inch N1 foldable TV. 98
• Figure 15. Flex Note Extendable™. 99
• Figure 16. Flex In & Out Flip. 99
• Figure 17. Traxcon printed lighting circuitry. 105
• Figure 18. Global Sensor Market Roadmap. 113
• Figure 19. Market Roadmap for Wrist-worn Wearables. 116
• Figure 20. Market Roadmap for Smart Bands. 117
• Figure 21. Market Roadmap for Smart Glasses. 117
• Figure 22. Market Roadmap for Smart Clothing and Accessories. 118
• Figure 23. Market Roadmap of Market Trends for Skin-Patches. 119
• Figure 24. Market Roadmap for Smart Rings. 120
• Figure 25.Market Roadmap for Hearables. 120
• Figure 26. Market Roadmap for Head Mounted Wearables. 122
• Figure 27. Roadmap for Wearable Optical Heart-rate Sensors. 131
• Figure 28. SWOT analysis for printed electronics. 171
• Figure 29. SWOT analysis for 3D electronics. 174
• Figure 30. SWOT analysis for analogue printing. 177
• Figure 31. SWOT analysis for digital printing. 179
• Figure 32. In-mold electronics prototype devices and products. 180
• Figure 33. SWOT analysis for In-Mold Electronics. 183
• Figure 34. SWOT analysis for R2R manufacturing. 186
• Figure 35. The molecular mechanism of the shape memory effect under different stimuli. 192
• Figure 36. Supercooled Soldering™ Technology. 196
• Figure 37. Reflow soldering schematic. 197
• Figure 38. Schematic diagram of induction heating reflow. 198
• Figure 39. Types of conductive inks and applications. 200
• Figure 40. Copper based inks on flexible substrate. 205
• Figure 41. SWOT analysis for Printable semiconductors. 214
• Figure 42. SWOT analysis for Printable sensor materials. 217
• Figure 43. RFID Tag with Nano Copper Antenna on Paper. 219
• Figure 44. SWOT analysis for flexible integrated circuits. 226
• Figure 45. Fully-printed organic thin-film transistors and circuitry on one-micron-thick polymer films. 227
• Figure 46. Flexible PCB. 230
• Figure 47. SWOT analysis for Flexible batteries. 233
• Figure 48. SWOT analysis for Flexible PV for energy harvesting. 236
• Figure 49. Roadmap of wearable sensor technology segmented by key biometrics. 241
• Figure 50. Wearable Technology Roadmap, by function. 248
• Figure 51. Actuator types. 249
• Figure 52. EmeTerm nausea relief wearable. 270
• Figure 53. Embr Wave for cooling and warming. 270
• Figure 54. dpl Wrist Wrap Light THerapy pain relief. 271
• Figure 55. Roadmap for Wrist-Worn Wearables. 273
• Figure 56. SWOT analysis for Wrist-worn wearables. 274
• Figure 57. FitBit Sense Watch. 275
• Figure 58. Wearable bio-fluid monitoring system for monitoring of hydration. 279
• Figure 59. Evolution of Ear-Worn Wearables. 283
• Figure 60. Nuheara IQbuds² Max. 283
• Figure 61. HP Hearing PRO OTC Hearing Aid. 289
• Figure 62. SWOT analysis for Ear worn wearables (hearables). 291
• Figure 63. Commercialization Timeline for Hearable Sensing Technologies. 294
• Figure 64. Roadmap of Market Trends for Hearables. 299
• Figure 65. Beddr SleepTuner. 305
• Figure 66. Global market for wearable consumer electronics 2020-2035 by type (Volume). 316
• Figure 67. Global market revenues for wearable consumer electronics, 2018-2035, (millions USD). 318
• Figure 68. The Apollo wearable device. 323
• Figure 69. Cyclops HMD. 326
• Figure 70. C2Sense sensors. 332
• Figure 71. Coachwhisperer device. 334
• Figure 72. Cogwear headgear. 335
• Figure 73. CardioWatch 287. 336
• Figure 74. FRENZ™ Brainband. 340
• Figure 75. NightOwl Home Sleep Apnea Test Device. 341
• Figure 76. eQ02+LIfeMontor. 343
• Figure 77. Cove wearable device. 346
• Figure 78. German bionic exoskeleton. 348
• Figure 79. UnlimitedHand. 349
• Figure 80. Apex Exosuit. 350
• Figure 81. Humanox Shin Guard. 354
• Figure 82. Airvida E1. 355
• Figure 83. Footrax. 356
• Figure 84. eMacula®. 357
• Figure 85. G2 Pro. 358
• Figure 86. REFLEX. 359
• Figure 87. Ring ZERO. 361
• Figure 88. Mawi Heart Patch. 363
• Figure 89. Ayo wearable light therapy. 370
• Figure 90. Nowatch. 371
• Figure 91. ORII smart ring. 373
• Figure 92. Proxxi Voltage. 377
• Figure 93. RealWear HMT-1. 378
• Figure 94. Moonwalkers from Shift Robotics Inc. 381
• Figure 95. SnowCookie device. 382
• Figure 96. Soter device. 383
• Figure 97. Feelzing Energy Patch. 388
• Figure 98. Wiliot tags. 395
• Figure 99. Connected human body and product examples. 402
• Figure 100. Companies and products in wearable health monitoring and rehabilitation devices and products. 406
• Figure 101. Smart e-skin system comprising health-monitoring sensors, displays, and ultra flexible PLEDs. 411
• Figure 102. Graphene medical patch. 414
• Figure 103. Graphene-based E-skin patch. 414
• Figure 104. Enfucell wearable temperature tag. 417
• Figure 105. TempTraQ wearable wireless thermometer. 418
• Figure 106. Technologies for minimally-invasive and non-invasive glucose detection. 419
• Figure 107. Schematic of non-invasive CGM sensor. 423
• Figure 108. Adhesive wearable CGM sensor. 423
• Figure 109. VitalPatch. 427
• Figure 110. Wearable ECG-textile. 427
• Figure 111. Wearable ECG recorder. 428
• Figure 112. Nexkin™. 429
• Figure 113. Bloomlife. 432
• Figure 114. Nanowire skin hydration patch. 433
• Figure 115. NIX sensors. 434
• Figure 116. Wearable sweat sensor. 435
• Figure 117. Wearable graphene sweat sensor. 436
• Figure 118. Gatorade's GX Sweat Patch. 436
• Figure 119. Sweat sensor incorporated into face mask. 437
• Figure 120. D-mine Pump. 438
• Figure 121. Lab-on-Skin™. 439
• Figure 122. My UV Patch. 441
• Figure 123. Overview layers of L'Oreal skin patch. 441
• Figure 124. Brilliantly Warm. 445
• Figure 125. Ava Fertility tracker. 445
• Figure 126. S9 Pro breast pump. 446
• Figure 127. Tempdrop. 446
• Figure 128. Digitsole Smartshoe. 447
• Figure 129. Schematic of smart wound dressing. 450
• Figure 130. REPAIR electronic patch concept. Image courtesy of the University of Pittsburgh School of Medicine. 451
• Figure 131. ABENA Nova smart diaper. 453
• Figure 132. Honda Walking Assist. 454
• Figure 133. ABLE Exoskeleton. 454
• Figure 134. ANGEL-LEGS-M10. 454
• Figure 135. AGADEXO Shoulder. 455
• Figure 136. Enyware. 455
• Figure 137. AWN-12 occupational powered hip exoskeleton. 455
• Figure 138. CarrySuit passive upper-body exoskeleton. 455
• Figure 139. Axosuit lower body medical exoskeleton. 456
• Figure 140. FreeGait. 456
• Figure 141. InMotion Arm. 456
• Figure 142. Biomotum SPARK. 456
• Figure 143. PowerWalk energy. 457
• Figure 144. Keeogo™. 457
• Figure 145. MATE-XT. 457
• Figure 146. CDYS passive shoulder support exoskeleton. 458
• Figure 147. ALDAK. 458
• Figure 148. HAL® Lower Limb. 458
• Figure 149. DARWING PA. 458
• Figure 150. Dephy ExoBoot. 459
• Figure 151. EksoNR. 459
• Figure 152. Emovo Assist. 459
• Figure 153. HAPO. 459
• Figure 154. Atlas passive modular exoskeleton. 460
• Figure 155. ExoAtlet II. 460
• Figure 156. ExoHeaver. 460
• Figure 157. Exy ONE. 461
• Figure 158. ExoArm. 461
• Figure 159. ExoMotus. 461
• Figure 160. Gloreha Sinfonia. 462
• Figure 161. BELK Knee Exoskeleton. 462
• Figure 162. Apex exosuit. 462
• Figure 163. Honda Walking Assist. 463
• Figure 164. BionicBack. 463
• Figure 165. Muscle Suit. 463
• Figure 166.Japet.W powered exoskeleton. 464
• Figure 167.Ski~Mojo. 464
• Figure 168. AIRFRAME passive shoulder. 464
• Figure 169.FORTIS passive tool holding exoskeleton. 465
• Figure 170. Integrated Soldier Exoskeleton (UPRISE®). 465
• Figure 171.UNILEXA passive exoskeleton. 465
• Figure 172.HandTutor. 466
• Figure 173.MyoPro®. 466
• Figure 174.Myosuit. 466
• Figure 175. archelis wearable chair. 466
• Figure 176.Chairless Chair. 467
• Figure 177.Indego. 467
• Figure 178. Polyspine. 467
• Figure 179. Hercule powered lower body exoskeleton. 468
• Figure 180. ReStore Soft Exo-Suit. 468
• Figure 181. Hand of Hope. 468
• Figure 182. REX powered exoskeleton. 468
• Figure 183. Elevate Ski Exoskeleton. 469
• Figure 184. UGO210 exoskeleton. 469
• Figure 185. EsoGLOVE Pro. 469
• Figure 186. Roki. 469
• Figure 187. Powered Clothing. 470
• Figure 188. Againer shock absorbing exoskeleton. 470
• Figure 189. EasyWalk Assistive Soft Exoskeleton Walker. 470
• Figure 190. Skel-Ex. 470
• Figure 191. EXO-H3 lower limbs robotic exoskeleton. 471
• Figure 192. Ikan Tilta Max Armor-Man 2 471
• Figure 193. AMADEO hand and finger robotic rehabilitation device. 471
• Figure 194.Atalante autonomous lower-body exoskeleton. 472
• Figure 195. Global Market for Wearable Medical & Healthcare Electronics 2020-2035 (Million Units). 473
• Figure 196. Global market for Wearable medical & healthcare electronics, 2020-2035, millions of US dollars. 474
• Figure 197. Libre 3. 478
• Figure 198. Libre Sense Glucose Sport Biowearable. 478
• Figure 199. AcuPebble SA100. 479
• Figure 200. Vitalgram®. 482
• Figure 201. Alertgy NICGM wristband. 484
• Figure 202. ALLEVX. 485
• Figure 203. Gastric Alimetry. 486
• Figure 204. Alva Health stroke monitor. 487
• Figure 205. amofit S. 488
• Figure 206. MIT and Amorepacific's chip-free skin sensor. 489
• Figure 207. Sigi™ Insulin Management System. 491
• Figure 208. The Apollo wearable device. 493
• Figure 209. Apos3. 494
• Figure 210. Artemis is smart clothing system. 496
• Figure 211. KneeStim. 497
• Figure 212. PaciBreath. 500
• Figure 213. Structure of Azalea Vision’s smart contact lens. 501
• Figure 214. Belun® Ring. 503
• Figure 215. Neuronaute wearable. 511
• Figure 216. biped.ai device. 513
• Figure 217. circul+ smart ring. 515
• Figure 218. Cala Trio. 519
• Figure 219. BioSleeve®. 526
• Figure 220. Cognito's gamma stimulation device. 528
• Figure 221. Cogwear Headband. 528
• Figure 222. First Relief. 535
• Figure 223. Jewel Patch Wearable Cardioverter Defibrillator . 539
• Figure 224. enFuse. 541
• Figure 225. EOPatch. 543
• Figure 226. Epilog. 545
• Figure 227. FloPatch. 552
• Figure 228. Hinge Health wearable therapy devices. 564
• Figure 229. MYSA - 'Relax Shirt'. 565
• Figure 230. Atusa system. 574
• Figure 231. Kenzen ECHO Smart Patch. 578
• Figure 232. The Kernel Flow headset. 579
• Figure 233. KnowU™. 581
• Figure 234. LifeSpan patch. 589
• Figure 235. Mawi Heart Patch. 593
• Figure 236. WalkAid. 599
• Figure 237. Monarch™ Wireless Wearable Biosensor 600
• Figure 238. Modoo device. 604
• Figure 239. Munevo Drive. 608
• Figure 240. Electroskin integration schematic. 611
• Figure 241. Modius Sleep wearable device. 616
• Figure 242. Neuphony Headband. 617
• Figure 243. Nix Biosensors patch. 621
• Figure 244. Otolith wearable device. 625
• Figure 245. Peerbridge Cor. 629
• Figure 246. Point Fit Technology skin patch. 633
• Figure 247. Sylvee 1.0. 639
• Figure 248. RootiRx. 643
• Figure 249. Sylvee 1.0. 645
• Figure 250. Silvertree Reach. 657
• Figure 251. Smardii smart diaper. 660
• Figure 252. Subcuject. 667
• Figure 253. Nerivio. 671
• Figure 254. Feelzing Energy Patch. 672
• Figure 255. Ultrahuman wearable glucose monitor. 674
• Figure 256. Vaxxas patch. 677
• Figure 257. S-Patch Ex. 687
• Figure 258. Zeit Medical Wearable Headband. 690
• Figure 259. Evolution of Smart Eyewear. 692
• Figure 260. Engo Eyewear. 703
• Figure 261. Lenovo ThinkReality A3. 704
• Figure 262. Magic Leap 1. 704
• Figure 263. Microsoft HoloLens 2. 705
• Figure 264. OPPO Air Glass AR. 705
• Figure 265. Snap Spectacles AR (4th gen). 705
• Figure 266. Vuzix Blade Upgraded. 706
• Figure 267. NReal Light MR smart glasses. 710
• Figure 268. Schematic for configuration of full colour microLED display 712
• Figure 269. BOE glass-based backplane process. 713
• Figure 270. MSI curved quantum dot miniLED display. 714
• Figure 271. Nanolumi Chameleon® G Film in LED/LCD Monitor. 715
• Figure 272. Vuzix microLED microdisplay Smart Glasses. 716
• Figure 273. Pixels per inch roadmap of µ-LED displays from 2007 to 2019. 717
• Figure 274. Mass transfer for µLED chips. 718
• Figure 275. Schematic diagram of mass transfer technologies. 720
• Figure 276. Comparison of microLED with other display technologies. 723
• Figure 277. Lextar 10.6 inch transparent microLED display. 724
• Figure 278. Transition to borderless design. 724
• Figure 279. Mojo Vision smart contact lens with an embedded MicroLED display. 726
• Figure 280. Global market for gaming and entertainment wearable technology, 2020-2035 (Million Units). 728
• Figure 281. Global market for gaming and entertainment wearable technology, 2020-2035, millions of US dollars. 729
• Figure 282. Skinetic vest. 730
• Figure 283. IntelliPix™ design for 0.26″ 1080p microLED display. 738
• Figure 284. Dapeng DPVR P1 Pro 4k VR all-in-one VR glasses. 739
• Figure 285. Vive Focus 3 VR headset Wrist Tracker. 749
• Figure 286. Huawei smart glasses. 750
• Figure 287. Jade Bird Display micro displays. 755
• Figure 288. JBD's 0.13-inch panel. 755
• Figure 289. 0.22” Monolithic full colour microLED panel and inset shows a conceptual monolithic polychrome projector with a waveguide. 756
• Figure 290. Kura Technologies' AR Glasses. 759
• Figure 291. Smart contact lenses schematic. 769
• Figure 292. OQmented technology for AR smart glasses. 772
• Figure 293. VISIRIUM® Technology smart glasses prototype. 777
• Figure 294. SenseGlove Nova. 778
• Figure 295. MeganeX. 779
• Figure 296. A micro-display with a stacked-RGB pixel array, where each pixel is an RGB-emitting stacked microLED device (left). The micro-display showing a video of fireworks at night, demonstrating the full-colour capability (right). N.B. Areas around the display 782
• Figure 297. JioGlass mixed reality glasses type headset. 783
• Figure 298. Vuzix uLED display engine. 792
• Figure 299. Xiaomi Smart Glasses. 793
• Figure 300. SWOT analysis for printed, flexible and hybrid electronics in E-textiles. 800
• Figure 301. Timeline of the different generations of electronic textiles. 802
• Figure 302. Examples of each generation of electronic textiles. 802
• Figure 303. Conductive yarns. 806
• Figure 304. Electronics integration in textiles: (a) textile-adapted, (b) textile-integrated (c) textile-basd. 808
• Figure 305. Stretchable polymer encapsulation microelectronics on textiles. 814
• Figure 306. Wove Band. 815
• Figure 307. Wearable graphene medical sensor. 816
• Figure 308. Conductive yarns. 818
• Figure 309. Classification of conductive materials and process technology. 819
• Figure 310. Structure diagram of Ti3C2Tx. 828
• Figure 311. Structure of hexagonal boron nitride. 829
• Figure 312. BN nanosheet textiles application. 830
• Figure 313. SEM image of cotton fibers with PEDOT:PSS coating. 832
• Figure 314. Schematic of inkjet-printed processes. 837
• Figure 315: Silver nanocomposite ink after sintering and resin bonding of discrete electronic components. 842
• Figure 316. Schematic summary of the formulation of silver conductive inks. 843
• Figure 317. Copper based inks on flexible substrate. 845
• Figure 318: Schematic of single-walled carbon nanotube. 848
• Figure 319. Stretchable SWNT memory and logic devices for wearable electronics. 849
• Figure 320. Graphene layer structure schematic. 851
• Figure 321. BGT Materials graphene ink product. 852
• Figure 322. PCM cooling vest. 855
• Figure 323. SMPU-treated cotton fabrics. 855
• Figure 324. Schematics of DIAPLEX membrane. 856
• Figure 325. SMP energy storage textiles. 857
• Figure 326. Nike x Acronym Blazer Sneakers. 861
• Figure 327. Adidas 3D Runner Pump. 861
• Figure 328. Under Armour Archi-TechFuturist. 861
• Figure 329. Reebok Reebok Liquid Speed. 861
• Figure 330. Radiate sports vest. 862
• Figure 331. Adidas smart insole. 865
• Figure 332. Applications of E-textiles. 869
• Figure 333. EXO2 Stormwalker 2 Heated Jacket. 871
• Figure 334. Flexible polymer-based heated glove, sock and slipper. 873
• Figure 335. ThermaCell Rechargeable Heated Insoles. 874
• Figure 336. Myant sleeve tracks biochemical indicators in sweat. 876
• Figure 337. Flexible polymer-based therapeutic products. 877
• Figure 338. iStimUweaR . 878
• Figure 339. Digitsole Smartshoe. 883
• Figure 340. Basketball referee Royole fully flexible display. 886
• Figure 341. A mechanical glove, Robo-Glove, with pressure sensors and other sensors jointly developed by General Motors and NASA. 888
• Figure 342. Power supply mechanisms for electronic textiles and wearables. 890
• Figure 343. Micro-scale energy scavenging techniques. 893
• Figure 344. Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper. 895
• Figure 345. 3D printed piezoelectric material. 896
• Figure 346. Application of electronic textiles in AR/VR. 898
• Figure 347. Global market for printed and flexible E-textiles and smart apparel electronics, 2020-2035 (Million Units). 900
• Figure 348. Global market for printed and flexible E-textiles and smart apparel electronics, 2020-2035, millions of US dollars. 901
• Figure 349. BioMan+. 906
• Figure 350. EXO Glove. 906
• Figure 351. LED hooded jacket. 910
• Figure 352. Heated element module. 911
• Figure 353. Carhartt X-1 Smart Heated Vest. 919
• Figure 354. Cionic Neural Sleeve. 921
• Figure 355. Graphene dress. The dress changes colour in sync with the wearer’s breathing. 924
• Figure 356. Descante Solar Thermo insulated jacket. 925
• Figure 357. G+ Graphene Aero Jersey. 926
• Figure 358. HiFlex strain/pressure sensor. 935
• Figure 359. KiTT motion tracking knee sleeve. 937
• Figure 360. Healables app-controlled electrotherapy device. 943
• Figure 361. LumeoLoop device. 956
• Figure 362. Electroskin integration schematic. 962
• Figure 363. Nextiles’ compression garments. 964
• Figure 364. Nextiles e-fabric. 964
• Figure 365 .Nuada. 967
• Figure 366. Palarum PUP smart socks. 972
• Figure 367. Smardii smart diaper. 983
• Figure 368. Softmatter compression garment. 985
• Figure 369. Softmatter sports bra with a woven ECG sensor. 985
• Figure 370. MoCap Pro Glove. 987
• Figure 371. Teslasuit. 991
• Figure 372. ZOZOFIT wearable at-home 3D body scanner. 1004
• Figure 373. YouCare smart shirt. 1005
• Figure 374. SWOT analysis for printed, flexible and hybrid electronics in energy. 1009
• Figure 375. Examples of Flexible batteries on the market. 1010
• Figure 376. Stretchable lithium-ion battery for flexible electronics 1012
• Figure 377. Loomia E-textile. 1012
• Figure 378. BrightVolt battery. 1013
• Figure 379. ProLogium solid-state technology. 1014
• Figure 380. Amprius Li-ion batteries. 1015
• Figure 381. MOLEX thin-film battery. 1016
• Figure 382. Flexible batteries on the market. 1017
• Figure 383. Various architectures for flexible and stretchable electrochemical energy storage. 1020
• Figure 384. Types of flexible batteries. 1022
• Figure 385. Materials and design structures in flexible lithium ion batteries. 1023
• Figure 386. Flexible/stretchable LIBs with different structures. 1025
• Figure 387. a–c) Schematic illustration of coaxial (a), twisted (b), and stretchable (c) LIBs. 1028
• Figure 388. a) Schematic illustration of the fabrication of the superstretchy LIB based on an MWCNT/LMO composite fiber and an MWCNT/LTO composite fiber. b,c) Photograph (b) and the schematic illustration (c) of a stretchable fiber-shaped battery under stretching conditions. d) Schematic illustration of the spring-like stretchable LIB. e) SEM images of a fiberat different strains. f) Evolution of specific capacitance with strain. d–f) 1029
• Figure 389. Origami disposable battery. 1030
• Figure 390. Zn–MnO2 batteries produced by Brightvolt. 1032
• Figure 391. Various applications of printed paper batteries. 1033
• Figure 392.Schematic representation of the main components of a battery. 1033
• Figure 393. Schematic of a printed battery in a sandwich cell architecture, where the anode and cathode of the battery are stacked together. 1035
• Figure 394. Sakuú's Swift Print 3D-printed solid-state battery cells. 1046
• Figure 395. Manufacturing Processes for Conventional Batteries (I), 3D Microbatteries (II), and 3D-Printed Batteries (III). 1047
• Figure 396. Examples of applications of thin film batteries. 1054
• Figure 397. Capacities and voltage windows of various cathode and anode materials. 1055
• Figure 398. Traditional lithium-ion battery (left), solid state battery (right). 1057
• Figure 399. Stretchable lithium-air battery for wearable electronics. 1060
• Figure 400. Ag–Zn batteries produced by Imprint Energy. 1063
• Figure 401. Transparent batteries. 1068
• Figure 402. Degradable batteries. 1070
• Figure 403 . Fraunhofer IFAM printed electrodes. 1074
• Figure 404. Ragone plots of diverse batteries and the commonly used electronics powered by flexible batteries. 1075
• Figure 405. Schematic of the structure of stretchable LIBs. 1080
• Figure 406. Electrochemical performance of materials in flexible LIBs. 1080
• Figure 407. Main printing methods for supercapacitors. 1092
• Figure 408. Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper. 1101
• Figure 409. Origami-like silicon solar cells. 1102
• Figure 410. Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper. 1104
• Figure 411. Concept of microwave-transparent heaters for automotive radars. 1107
• Figure 412. Defrosting and defogging transparent heater applications. 1108
• Figure 413. Global market for printed and flexible energy storage, generation and harvesting electronics, 2020-2035 by type (Volume). 1120
• Figure 414. Global market for printed and flexible energy storage, generation and harvesting electronics, 2020-2035, millions of US dollars. 1122
• Figure 415. 3DOM battery. 1123
• Figure 416. AC biode prototype. 1125
• Figure 417. Ampcera’s all-ceramic dense solid-state electrolyte separator sheets (25 um thickness, 50mm x 100mm size, flexible and defect free, room temperature ionic conductivity ~1 mA/cm). 1127
• Figure 418. Ateios thin-film, printed battery. 1128
• Figure 419. 3D printed lithium-ion battery. 1131
• Figure 420. TempTraq wearable patch. 1132
• Figure 421. SoftBattery®. 1134
• Figure 422. Roll-to-roll equipment working with ultrathin steel substrate. 1135
• Figure 423. TAeTTOOz printable battery materials. 1136
• Figure 424. Exeger Powerfoyle. 1137
• Figure 425. 2D paper batteries. 1140
• Figure 426. 3D Custom Format paper batteries. 1140
• Figure 427. Hitachi Zosen solid-state battery. 1141
• Figure 428. Ilika solid-state batteries. 1143
• Figure 429. TAeTTOOz printable battery materials. 1144
• Figure 430. LiBEST flexible battery. 1147
• Figure 431. 3D solid-state thin-film battery technology. 1149
• Figure 432. Schematic illustration of three-chamber system for SWCNH production. 1151
• Figure 433. TEM images of carbon nanobrush. 1152
• Figure 434. Printed Energy flexible battery. 1155
• Figure 435. Printed battery. 1156
• Figure 436. ProLogium solid-state battery. 1157
• Figure 437. Sakuú Corporation 3Ah Lithium Metal Solid-state Battery. 1159
• Figure 438. Samsung SDI's sixth-generation prismatic batteries. 1160
• Figure 439. Grepow flexible battery. 1163