The Global Market For Advanced Batteries 2024-2034 - Nanotech Magazine

הועלה מחדש על ידי אפלטון

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Li-ion, Lithium-Metal, Lithium-Sulfur, Lithium Titanate & Niobate, Sodium-ion, Aluminium-ion, All-solid state batteries (ASSBs), Flexible, Transparent, Degradable, Printed, Redox Flow, and Zinc.

פורסם: דצמבר 2023
עמודים: 563
שולחנות: 106
דמויות: 155

Advanced, rechargeable batteries with very high efficiency are a key technology, enabling improved energy generation and storage for a wide range of applications. Their use will accelerate progress towards sustainable and smart solutions to current energy problems. The Global Market for Advanced Batteries 2024-2034 covers the whole range of advanced battery technologies utilized in markets including Electric Vehicles and Transportation, Consumer Electronics, Grid Storage and Stationary Battery markets.

This 500+ page market report provides a comprehensive analysis of the global advanced battery market to 2034. It covers all advanced battery technologies including lithium-ion, lithium-metal, lithium-sulfur, sodium-ion, aluminum-ion, redox flow, zinc-based, solid-state, flexible, transparent, printed, and more.

The report analyzes the global market by battery type, end-use market, key technologies, materials, major players, product developments, SWOT analyses, and more. It includes historical data from 2018-2022 and market forecasts to 2034 segmented by battery types and end use markets. Battery technologies covered in depth:

ליתיום יון
Lithium-metal
Lithium-sulfur
נתרן-יון
Aluminium-ion
Redox flow
Zinc-based
מצב מוצק
גמיש
שקוף
נדפס

End-use markets analyzed include:

Electric vehicles and transportation (e.g. trains, trucks, boats)
Grid storage
מוצרי אלקטרוניקה
Stationary batteries

The report includes 300+ company profiles of all the key manufacturers, developers, and suppliers of advanced battery materials, components, technologies, and recycling. Profiles include overviews, products/technologies, manufacturing capabilities, partnerships, etc. Companies profiled include Atlas Materials, CMBlu Energy AG, Enerpoly, ESS Tech, Factorial, Flow Aluminum, Inc., Gotion High Tech, Graphene Manufacturing Group, High Performace Battery Holding AG, Inobat, Inx, Lyten, Our Next Energy (ONE), Sicona Battery Technologies, Sila, Solid Power, Stabl Energy, TasmanIon and VFlowTech.

1 שיטות מחקר 35

1.1 היקף דיווח 35
1.2 מתודולוגיית מחקר 35

2 מבוא 37

2.1 The global market for advanced batteries 37
- 2.1.1 Electric vehicles 39
  - 2.1.1.1 סקירת שוק 39
  - 2.1.1.2 Battery Electric Vehicles 39
  - 2.1.1.3 Electric buses, vans and trucks 40
    - 2.1.1.3.1 Electric medium and heavy duty trucks 41
    - 2.1.1.3.2 Electric light commercial vehicles (LCVs) 41
    - 2.1.1.3.3 Electric buses 42
    - 2.1.1.3.4 Micro EVs 43
  - 2.1.1.4 Electric off-road 44
    - 2.1.1.4.1 Construction vehicles 44
    - 2.1.1.4.2 Electric trains 46
    - 2.1.1.4.3 Electric boats 47
  - 2.1.1.5 Market demand and forecasts 49
- 2.1.2 Grid storage 52
  - 2.1.2.1 סקירת שוק 52
  - 2.1.2.2 Technologies 53
  - 2.1.2.3 Market demand and forecasts 54
- 2.1.3 אלקטרוניקה לצרכן 56
  - 2.1.3.1 סקירת שוק 56
  - 2.1.3.2 Technologies 56
  - 2.1.3.3 Market demand and forecasts 57
- 2.1.4 Stationary batteries 57
  - 2.1.4.1 סקירת שוק 57
  - 2.1.4.2 Technologies 59
  - 2.1.4.3 Market demand and forecasts 60
2.2 נהגי שוק 60
2.3 Battery market megatrends 63
2.4 Advanced materials for batteries 66
2.5 Motivation for battery development beyond lithium 66

3 TYPES OF BATTERIES 68

3.1 Battery chemistries 68
3.2 LI-ION BATTERIES 68
- 3.2.1 תיאור טכנולוגיה 68
  - 3.2.1.1 Types of Lithium Batteries 73
- 3.2.2 ניתוח SWOT 76
- 3.2.3 Anodes 77
  - 3.2.3.1 Materials 77
    - 3.2.3.1.1 Graphite 79
    - 3.2.3.1.2 Lithium Titanate 79
    - 3.2.3.1.3 Lithium Metal 79
    - 3.2.3.1.4 Silicon anodes 80
      - 3.2.3.1.4.1 הטבות 81
      - 3.2.3.1.4.2 Development in li-ion batteries 82
      - 3.2.3.1.4.3 Manufacturing silicon 83
      - 3.2.3.1.4.4 Costs 84
      - 3.2.3.1.4.5 יישומים 85
        
        3.2.3.1.4.5.1 EVs 86
      - 3.2.3.1.4.6 Future outlook 87
    - 3.2.3.1.5 Alloy materials 88
    - 3.2.3.1.6 Carbon nanotubes in Li-ion 88
    - 3.2.3.1.7 Graphene coatings for Li-ion 89
- 3.2.4 Li-ion electrolytes 89
- 3.2.5 Cathodes 90
  - 3.2.5.1 Materials 90
    - 3.2.5.1.1 High-nickel cathode materials 92
    - 3.2.5.1.2 Manufacturing 93
    - 3.2.5.1.3 High manganese content 94
    - 3.2.5.1.4 Li-Mn-rich cathodes 94
    - 3.2.5.1.5 Lithium Cobalt Oxide(LiCoO2) — LCO 95
    - 3.2.5.1.6 Lithium Iron Phosphate(LiFePO4) — LFP 96
    - 3.2.5.1.7 Lithium Manganese Oxide (LiMn2O4) — LMO 97
    - 3.2.5.1.8 Lithium Nickel Manganese Cobalt Oxide (LiNiMnCoO2) — NMC 98
    - 3.2.5.1.9 Lithium Nickel Cobalt Aluminum Oxide (LiNiCoAlO2) — NCA 99
    - 3.2.5.1.10 LMR-NMC 100
    - 3.2.5.1.11 Lithium manganese phosphate (LiMnP) 100
    - 3.2.5.1.12 Lithium manganese iron phosphate (LiMnFePO4 or LMFP) 101
    - 3.2.5.1.13 Lithium nickel manganese oxide (LNMO) 101
  - 3.2.5.2 Comparison of key lithium-ion cathode materials 102
  - 3.2.5.3 Emerging cathode material synthesis methods 102
  - 3.2.5.4 Cathode coatings 103
- 3.2.6 Binders and conductive additives 103
  - 3.2.6.1 Materials 103
- 3.2.7 Separators 104
  - 3.2.7.1 Materials 104
- 3.2.8 Platinum group metals 105
- 3.2.9 Li-ion battery market players 105
- 3.2.10 Li-ion recycling 106
  - 3.2.10.1 Comparison of recycling techniques 108
  - 3.2.10.2 Hydrometallurgy 110
    - 3.2.10.2.1 Method overview 110
      - 3.2.10.2.1.1 Solvent extraction 111
    - 3.2.10.2.2 SWOT analysis 112
  - 3.2.10.3 Pyrometallurgy 113
    - 3.2.10.3.1 Method overview 113
    - 3.2.10.3.2 SWOT analysis 114
  - 3.2.10.4 Direct recycling 115
    - 3.2.10.4.1 Method overview 115
      - 3.2.10.4.1.1 Electrolyte separation 116
      - 3.2.10.4.1.2 Separating cathode and anode materials 117
      - 3.2.10.4.1.3 Binder removal 117
      - 3.2.10.4.1.4 Relithiation 117
      - 3.2.10.4.1.5 Cathode recovery and rejuvenation 118
      - 3.2.10.4.1.6 Hydrometallurgical-direct hybrid recycling 119
    - 3.2.10.4.2 SWOT analysis 120
  - 3.2.10.5 Other methods 121
    - 3.2.10.5.1 Mechanochemical Pretreatment 121
    - 3.2.10.5.2 Electrochemical Method 121
    - 3.2.10.5.3 Ionic Liquids 121
  - 3.2.10.6 Recycling of Specific Components 122
    - 3.2.10.6.1 Anode (Graphite) 122
    - 3.2.10.6.2 Cathode 122
    - 3.2.10.6.3 Electrolyte 123
  - 3.2.10.7 Recycling of Beyond Li-ion Batteries 123
    - 3.2.10.7.1 Conventional vs Emerging Processes 123
- 3.2.11 Global revenues 125
3.3 LITHIUM-METAL BATTERIES 126
- 3.3.1 תיאור טכנולוגיה 126
- 3.3.2 Lithium-metal anodes 127
- 3.3.3 אתגרים 127
- 3.3.4 Energy density 128
- 3.3.5 Anode-less Cells 129
- 3.3.6 Lithium-metal and solid-state batteries 129
- 3.3.7 יישומים 130
- 3.3.8 ניתוח SWOT 131
- 3.3.9 מפתחי מוצר 132
3.4 LITHIUM-SULFUR BATTERIES 133
- 3.4.1 תיאור טכנולוגיה 133
  - 3.4.1.1 Advantages 133
  - 3.4.1.2 אתגרים 134
  - 3.4.1.3 Commercialization 135
- 3.4.2 ניתוח SWOT 136
- 3.4.3 הכנסות גלובליות 137
- 3.4.4 מפתחי מוצר 138
3.5 LITHIUM TITANATE AND NIOBATE BATTERIES 139
- 3.5.1 תיאור טכנולוגיה 139
- 3.5.2 Niobium titanium oxide (NTO) 139
  - 3.5.2.1 Niobium tungsten oxide 140
  - 3.5.2.2 Vanadium oxide anodes 141
- 3.5.3 הכנסות גלובליות 142
- 3.5.4 מפתחי מוצר 142
3.6 SODIUM-ION (NA-ION) BATTERIES 144
- 3.6.1 תיאור טכנולוגיה 144
  - 3.6.1.1 Cathode materials 144
    - 3.6.1.1.1 Layered transition metal oxides 144
      - 3.6.1.1.1.1 סוגים 144
      - 3.6.1.1.1.2 Cycling performance 145
      - 3.6.1.1.1.3 Advantages and disadvantages 146
      - 3.6.1.1.1.4 Market prospects for LO SIB 146
    - 3.6.1.1.2 Polyanionic materials 147
      - 3.6.1.1.2.1 Advantages and disadvantages 148
      - 3.6.1.1.2.2 סוגים 148
      - 3.6.1.1.2.3 Market prospects for Poly SIB 148
    - 3.6.1.1.3 Prussian blue analogues (PBA) 149
      - 3.6.1.1.3.1 סוגים 149
      - 3.6.1.1.3.2 Advantages and disadvantages 150
      - 3.6.1.1.3.3 Market prospects for PBA-SIB 151
  - 3.6.1.2 Anode materials 152
    - 3.6.1.2.1 Hard carbons 152
    - 3.6.1.2.2 Carbon black 154
    - 3.6.1.2.3 Graphite 155
    - 3.6.1.2.4 Carbon nanotubes 158
    - 3.6.1.2.5 Graphene 159
    - 3.6.1.2.6 Alloying materials 161
    - 3.6.1.2.7 Sodium Titanates 162
    - 3.6.1.2.8 Sodium Metal 162
  - 3.6.1.3 Electrolytes 162
- 3.6.2 Comparative analysis with other battery types 164
- 3.6.3 Cost comparison with Li-ion 165
- 3.6.4 Materials in sodium-ion battery cells 165
- 3.6.5 ניתוח SWOT 168
- 3.6.6 הכנסות גלובליות 169
- 3.6.7 מפתחי מוצר 170
  - 3.6.7.1 Battery Manufacturers 170
  - 3.6.7.2 Large Corporations 170
  - 3.6.7.3 Automotive Companies 170
  - 3.6.7.4 Chemicals and Materials Firms 171
3.7 SODIUM-SULFUR BATTERIES 172
- 3.7.1 תיאור טכנולוגיה 172
- 3.7.2 יישומים 173
- 3.7.3 ניתוח SWOT 174
3.8 ALUMINIUM-ION BATTERIES 176
- 3.8.1 תיאור טכנולוגיה 176
- 3.8.2 ניתוח SWOT 177
- 3.8.3 Commercialization 178
- 3.8.4 הכנסות גלובליות 179
- 3.8.5 מפתחי מוצר 179
3.9 ALL-SOLID STATE BATTERIES (ASSBs) 181
- 3.9.1 תיאור טכנולוגיה 181
  - 3.9.1.1 Solid-state electrolytes 182
- 3.9.2 Features and advantages 183
- 3.9.3 Technical specifications 184
- 3.9.4 סוגים 187
- 3.9.5 Microbatteries 189
  - 3.9.5.1 Introduction 189
  - 3.9.5.2 Materials 190
  - 3.9.5.3 יישומים 190
  - 3.9.5.4 3D designs 190
    - 3.9.5.4.1 3D printed batteries 191
- 3.9.6 Bulk type solid-state batteries 191
- 3.9.7 ניתוח SWOT 192
- 3.9.8 Limitations 194
- 3.9.9 הכנסות גלובליות 195
- 3.9.10 מפתחי מוצר 197
3.10 FLEXIBLE BATTERIES 198
- 3.10.1 Technology description 198
- 3.10.2 Technical specifications 200
  - 3.10.2.1 Approaches to flexibility 201
- 3.10.3 Flexible electronics 203
  - 3.10.3.1 Flexible materials 204
- 3.10.4 Flexible and wearable Metal-sulfur batteries 205
- 3.10.5 Flexible and wearable Metal-air batteries 206
- 3.10.6 Flexible Lithium-ion Batteries 207
  - 3.10.6.1 Electrode designs 210
  - 3.10.6.2 Fiber-shaped Lithium-Ion batteries 213
  - 3.10.6.3 Stretchable lithium-ion batteries 214
  - 3.10.6.4 Origami and kirigami lithium-ion batteries 216
- 3.10.7 Flexible Li/S batteries 216
  - 3.10.7.1 Components 217
  - 3.10.7.2 Carbon nanomaterials 217
- 3.10.8 Flexible lithium-manganese dioxide (Li–MnO2) batteries 218
- 3.10.9 Flexible zinc-based batteries 219
  - 3.10.9.1 Components 219
    - 3.10.9.1.1 Anodes 219
    - 3.10.9.1.2 Cathodes 220
  - 3.10.9.2 אתגרים 220
  - 3.10.9.3 Flexible zinc-manganese dioxide (Zn–Mn) batteries 221
  - 3.10.9.4 Flexible silver–zinc (Ag–Zn) batteries 222
  - 3.10.9.5 Flexible Zn–Air batteries 223
  - 3.10.9.6 Flexible zinc-vanadium batteries 223
- 3.10.10 Fiber-shaped batteries 224
  - 3.10.10.1 Carbon nanotubes 224
  - 3.10.10.2 Types 225
  - 3.10.10.3 יישומים 226
  - 3.10.10.4 אתגרים 226
- 3.10.11 Energy harvesting combined with wearable energy storage devices 227
- 3.10.12 SWOT analysis 229
- 3.10.13 Global revenues 230
- 3.10.14 Product developers 232
3.11 TRANSPARENT BATTERIES 233
- 3.11.1 Technology description 233
- 3.11.2 Components 234
- 3.11.3 SWOT analysis 235
- 3.11.4 תחזית שוק 237
3.12 DEGRADABLE BATTERIES 237
- 3.12.1 Technology description 237
- 3.12.2 Components 238
- 3.12.3 SWOT analysis 240
- 3.12.4 תחזית שוק 241
- 3.12.5 מפתחי מוצר 241
3.13 PRINTED BATTERIES 242
- 3.13.1 Technical specifications 242
- 3.13.2 Components 243
- 3.13.3 Design 245
- 3.13.4 Key features 246
- 3.13.5 Printable current collectors 246
- 3.13.6 Printable electrodes 247
- 3.13.7 Materials 247
- 3.13.8 יישומים 247
- 3.13.9 Printing techniques 248
- 3.13.10 Lithium-ion (LIB) printed batteries 250
- 3.13.11 Zinc-based printed batteries 251
- 3.13.12 3D Printed batteries 254
  - 3.13.12.1 3D Printing techniques for battery manufacturing 256
  - 3.13.12.2 Materials for 3D printed batteries 258
    - 3.13.12.2.1 Electrode materials 258
    - 3.13.12.2.2 Electrolyte Materials 258
- 3.13.13 SWOT analysis 259
- 3.13.14 Global revenues 260
- 3.13.15 Product developers 261
3.14 REDOX FLOW BATTERIES 263
- 3.14.1 Technology description 263
- 3.14.2 Vanadium redox flow batteries (VRFB) 264
- 3.14.3 Zinc-bromine flow batteries (ZnBr) 265
- 3.14.4 Polysulfide bromine flow batteries (PSB) 266
- 3.14.5 Iron-chromium flow batteries (ICB) 267
- 3.14.6 All-Iron flow batteries 267
- 3.14.7 Zinc-iron (Zn-Fe) flow batteries 268
- 3.14.8 Hydrogen-bromine (H-Br) flow batteries 269
- 3.14.9 Hydrogen-Manganese (H-Mn) flow batteries 270
- 3.14.10 Organic flow batteries 271
- 3.14.11 Hybrid Flow Batteries 272
  - 3.14.11.1 Zinc-Cerium Hybrid 272
  - 3.14.11.2 Zinc-Polyiodide Hybrid Flow Battery 272
  - 3.14.11.3 Zinc-Nickel Hybrid Flow Battery 273
  - 3.14.11.4 Zinc-Bromine Hybrid Flow Battery 274
  - 3.14.11.5 Vanadium-Polyhalide Flow Battery 274
- 3.14.12 Global revenues 275
- 3.14.13 Product developers 276
3.15 ZN-BASED BATTERIES 277
- 3.15.1 Technology description 277
  - 3.15.1.1 Zinc-Air batteries 277
  - 3.15.1.2 Zinc-ion batteries 279
  - 3.15.1.3 Zinc-bromide 279
- 3.15.2 תחזית שוק 280
- 3.15.3 מפתחי מוצר 281

4 פרופילי חברה 282 (296 פרופילי חברה)

5 הפניות 537

רשימת שולחנות

Table 1. Battery chemistries used in electric buses. 42
Table 2. Micro EV types 43
Table 3. Battery Sizes for Different Vehicle Types. 46
Table 4. Competing technologies for batteries in electric boats. 48
Table 5. Competing technologies for batteries in grid storage. 53
Table 6. Competing technologies for batteries in consumer electronics 56
Table 7. Competing technologies for sodium-ion batteries in grid storage. 59
Table 8. Market drivers for use of advanced materials and technologies in batteries. 60
Table 9. Battery market megatrends. 63
Table 10. Advanced materials for batteries. 66
Table 11. Commercial Li-ion battery cell composition. 69
Table 12. Lithium-ion (Li-ion) battery supply chain. 72
Table 13. Types of lithium battery. 73
Table 14. Li-ion battery anode materials. 77
Table 15. Manufacturing methods for nano-silicon anodes. 83
Table 16. Markets and applications for silicon anodes. 85
Table 17. Li-ion battery cathode materials. 91
Table 18. Key technology trends shaping lithium-ion battery cathode development. 91
Table 19. Properties of Lithium Cobalt Oxide) as a cathode material for lithium-ion batteries. 96
Table 20. Properties of lithium iron phosphate (LiFePO4 or LFP) as a cathode material for lithium-ion batteries. 97
Table 21. Properties of Lithium Manganese Oxide cathode material. 98
Table 22. Properties of Lithium Nickel Manganese Cobalt Oxide (NMC). 99
Table 23. Properties of Lithium Nickel Cobalt Aluminum Oxide 100
Table 24. Comparison table of key lithium-ion cathode materials 102
Table 25. Li-ion battery Binder and conductive additive materials. 104
Table 26. Li-ion battery Separator materials. 105
Table 27. Li-ion battery market players. 106
Table 28. Typical lithium-ion battery recycling process flow. 107
Table 29. Main feedstock streams that can be recycled for lithium-ion batteries. 108
Table 30. Comparison of LIB recycling methods. 108
Table 31. Comparison of conventional and emerging processes for recycling beyond lithium-ion batteries. 124
Table 32. Global revenues for Li-ion batteries, 2018-2034, by market (Billions USD). 125
Table 33. Applications for Li-metal batteries. 130
Table 34. Li-metal battery developers 132
Table 35. Comparison of the theoretical energy densities of lithium-sulfur batteries versus other common battery types. 134
Table 36. Global revenues for Lithium-sulfur, 2018-2034, by market (Billions USD). 137
Table 37. Lithium-sulphur battery product developers. 138
Table 38. Product developers in Lithium titanate and niobate batteries. 142
Table 39. Comparison of cathode materials. 144
Table 40. Layered transition metal oxide cathode materials for sodium-ion batteries. 144
Table 41. General cycling performance characteristics of common layered transition metal oxide cathode materials. 145
Table 42. Polyanionic materials for sodium-ion battery cathodes. 147
Table 43. Comparative analysis of different polyanionic materials. 147
Table 44. Common types of Prussian Blue Analogue materials used as cathodes or anodes in sodium-ion batteries. 150
Table 45. Comparison of Na-ion battery anode materials. 152
Table 46. Hard Carbon producers for sodium-ion battery anodes. 153
Table 47. Comparison of carbon materials in sodium-ion battery anodes. 154
Table 48. Comparison between Natural and Synthetic Graphite. 156
טבלה 49. תכונות של גרפן, תכונות של חומרים מתחרים, יישומיו. 160
Table 50. Comparison of carbon based anodes. 161
Table 51. Alloying materials used in sodium-ion batteries. 161
Table 52. Na-ion electrolyte formulations. 163
Table 53. Pros and cons compared to other battery types. 164
Table 54. Cost comparison with Li-ion batteries. 165
Table 55. Key materials in sodium-ion battery cells. 165
Table 56. Product developers in aluminium-ion batteries. 179
Table 57. Types of solid-state electrolytes. 182
Table 58. Market segmentation and status for solid-state batteries. 183
Table 59. Typical process chains for manufacturing key components and assembly of solid-state batteries. 184
Table 60. Comparison between liquid and solid-state batteries. 188
Table 61. Limitations of solid-state thin film batteries. 194
Table 62. Global revenues for All-Solid State Batteries, 2018-2034, by market (Billions USD). 195
Table 63. Solid-state thin-film battery market players. 197
Table 64. Flexible battery applications and technical requirements. 199
Table 65. Flexible Li-ion battery prototypes. 208
Table 66. Electrode designs in flexible lithium-ion batteries. 210
Table 67. Summary of fiber-shaped lithium-ion batteries. 213
Table 68. Types of fiber-shaped batteries. 225
Table 69. Global revenues for flexible batteries, 2018-2034, by market (Billions USD). 230
Table 70. Product developers in flexible batteries. 232
Table 71. Components of transparent batteries. 234
Table 72. Components of degradable batteries. 238
Table 73. Product developers in degradable batteries. 241
Table 74. Main components and properties of different printed battery types. 244
Table 75. Applications of printed batteries and their physical and electrochemical requirements. 248
Table 76. 2D and 3D printing techniques. 248
Table 77. Printing techniques applied to printed batteries. 250
Table 78. Main components and corresponding electrochemical values of lithium-ion printed batteries. 250
Table 79. Printing technique, main components and corresponding electrochemical values of printed batteries based on Zn–MnO2 and other battery types. 252
Table 80. Main 3D Printing techniques for battery manufacturing. 256
Table 81. Electrode Materials for 3D Printed Batteries. 258
Table 82. Global revenues for printed batteries, 2018-2034, by market (Billions USD). 260
Table 83. Product developers in printed batteries. 261
Table 84. Advantages and disadvantages of redox flow batteries. 264
טבלה 85. סוללות זרימת חיזור ונדיום (VRFB) - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 264
טבלה 86. סוללות זרימת אבץ-ברום (ZnBr) - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 265
Table 87. Polysulfide bromine flow batteries (PSB)-key features, advantages, limitations, performance, components and applications. 266
טבלה 88. סוללות זרימת ברזל-כרום (ICB) - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 267
טבלה 89. סוללות זרימת כל ברזל - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 267
טבלה 90. סוללות זרימת אבץ-ברזל (Zn-Fe)-תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 268
טבלה 91. סוללות זרימת מימן-ברום (H-Br) - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 269
טבלה 92. סוללות זרימת מימן-מנגן (H-Mn) - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 270
טבלה 93. סוללות זרימה אורגנית - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 271
טבלה 94. סוללות זרימה היברידית של אבץ-צריום - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 272
טבלה 95. סוללות זרימה היברידית אבץ-פולייודיד - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 273
טבלה 96. סוללות זרימת אבץ-ניקל היברידית - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 273
טבלה 97. סוללות זרימת אבץ-ברום היברידית - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 274
טבלה 98. סוללות זרימה היברידית של ונדיום-פוליהאליד - תכונות מפתח, יתרונות, מגבלות, ביצועים, רכיבים ויישומים. 274
Table 99. Redox flow batteries product developers. 276
Table 100. ZN-based battery product developers. 281
Table 101. CATL sodium-ion battery characteristics. 328
Table 102. CHAM sodium-ion battery characteristics. 333
Table 103. Chasm SWCNT products. 334
Table 104. Faradion sodium-ion battery characteristics. 360
Table 105. HiNa Battery sodium-ion battery characteristics. 394
Table 106. Battery performance test specifications of J. Flex batteries. 414
Table 107. LiNa Energy battery characteristics. 431
Table 108. Natrium Energy battery characteristics. 450

רשימת דמויות

Figure 1. Annual sales of battery electric vehicles and plug-in hybrid electric vehicles. 38
Figure 2. Electric car Li-ion demand forecast (GWh), 2018-2034. 49
Figure 3. EV Li-ion battery market (US$B), 2018-2034. 50
Figure 4. Electric bus, truck and van battery forecast (GWh), 2018-2034. 51
Figure 5. Micro EV Li-ion demand forecast (GWh). 52
Figure 6. Lithium-ion battery grid storage demand forecast (GWh), 2018-2034. 55
Figure 7. Sodium-ion grid storage units. 55
Figure 8. Salt-E Dog mobile battery. 58
Figure 9. I.Power Nest – Residential Energy Storage System Solution. 59
איור 10. עלויות סוללות עד 2030. 65
Figure 11. Lithium Cell Design. 70
Figure 12. Functioning of a lithium-ion battery. 71
Figure 13. Li-ion battery cell pack. 71
Figure 14. Li-ion electric vehicle (EV) battery. 75
Figure 15. SWOT analysis: Li-ion batteries. 77
Figure 16. Silicon anode value chain. 81
Figure 17. Li-cobalt structure. 95
Figure 18. Li-manganese structure. 98
Figure 19. Typical direct, pyrometallurgical, and hydrometallurgical recycling methods for recovery of Li-ion battery active materials. 107
Figure 20. Flow chart of recycling processes of lithium-ion batteries (LIBs). 109
Figure 21. Hydrometallurgical recycling flow sheet. 111
Figure 22. SWOT analysis for Hydrometallurgy Li-ion Battery Recycling. 112
Figure 23. Umicore recycling flow diagram. 113
Figure 24. SWOT analysis for Pyrometallurgy Li-ion Battery Recycling. 114
Figure 25. Schematic of direct recyling process. 116
Figure 26. SWOT analysis for Direct Li-ion Battery Recycling. 120
Figure 27. Global revenues for Li-ion batteries, 2018-2034, by market (Billions USD). 126
Figure 28. Schematic diagram of a Li-metal battery. 126
Figure 29. SWOT analysis: Lithium-metal batteries. 132
Figure 30. Schematic diagram of Lithium–sulfur battery. 133
Figure 31. SWOT analysis: Lithium-sulfur batteries. 137
Figure 32. Global revenues for Lithium-sulfur, 2018-2034, by market (Billions USD). 138
Figure 33. Global revenues for Lithium titanate and niobate batteries, 2018-2034, by market (Billions USD). 142
Figure 34. Schematic of Prussian blue analogues (PBA). 149
איור 35. השוואה בין צילומי SEM של גרפיט טבעי בצורת כדור (NG; לאחר מספר שלבי עיבוד) וגראפיט סינטטי (SG). 155
Figure 36. Overview of graphite production, processing and applications. 157
Figure 37. Schematic diagram of a multi-walled carbon nanotube (MWCNT). 159
Figure 38. Schematic diagram of a Na-ion battery. 167
Figure 39. SWOT analysis: Sodium-ion batteries. 169
Figure 40. Global revenues for sodium-ion batteries, 2018-2034, by market (Billions USD). 169
Figure 41. Schematic of a Na–S battery. 172
Figure 42. SWOT analysis: Sodium-sulfur batteries. 175
Figure 43. Saturnose battery chemistry. 176
Figure 44. SWOT analysis: Aluminium-ion batteries. 178
Figure 45. Global revenues for aluminium-ion batteries, 2018-2034, by market (Billions USD). 179
Figure 46. Schematic illustration of all-solid-state lithium battery. 181
Figure 47. ULTRALIFE thin film battery. 182
Figure 48. Examples of applications of thin film batteries. 185
Figure 49. Capacities and voltage windows of various cathode and anode materials. 186
Figure 50. Traditional lithium-ion battery (left), solid state battery (right). 188
Figure 51. Bulk type compared to thin film type SSB. 192
Figure 52. SWOT analysis: All-solid state batteries. 193
Figure 53. Global revenues for All-Solid State Batteries, 2018-2034, by market (Billions USD). 196
Figure 54. Ragone plots of diverse batteries and the commonly used electronics powered by flexible batteries. 199
Figure 55. Flexible, rechargeable battery. 200
Figure 56. Various architectures for flexible and stretchable electrochemical energy storage. 201
Figure 57. Types of flexible batteries. 203
Figure 58. Flexible label and printed paper battery. 204
Figure 59. Materials and design structures in flexible lithium ion batteries. 207
Figure 60. Flexible/stretchable LIBs with different structures. 210
Figure 61. Schematic of the structure of stretchable LIBs. 211
Figure 62. Electrochemical performance of materials in flexible LIBs. 211
Figure 63. a–c) Schematic illustration of coaxial (a), twisted (b), and stretchable (c) LIBs. 214
Figure 64. 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) 215
Figure 65. Origami disposable battery. 216
Figure 66. Zn–MnO2 batteries produced by Brightvolt. 219
Figure 67. Charge storage mechanism of alkaline Zn-based batteries and zinc-ion batteries. 221
Figure 68. Zn–MnO2 batteries produced by Blue Spark. 222
Figure 69. Ag–Zn batteries produced by Imprint Energy. 222
Figure 70. Wearable self-powered devices. 228
Figure 71. SWOT analysis: Flexible batteries. 230
Figure 72. Global revenues for flexible batteries, 2018-2034, by market (Billions USD). 231
Figure 73. Transparent batteries. 234
Figure 74. SWOT analysis: Transparent batteries. 236
Figure 75. Degradable batteries. 237
Figure 76. SWOT analysis: Degradable batteries. 241
Figure 77. Various applications of printed paper batteries. 243
Figure 78.Schematic representation of the main components of a battery. 243
Figure 79. Schematic of a printed battery in a sandwich cell architecture, where the anode and cathode of the battery are stacked together. 245
Figure 80. Manufacturing Processes for Conventional Batteries (I), 3D Microbatteries (II), and 3D-Printed Batteries (III). 255
Figure 81. SWOT analysis: Printed batteries. 260
Figure 82. Global revenues for printed batteries, 2018-2034, by market (Billions USD). 261
Figure 83. Scheme of a redox flow battery. 263
Figure 84. Global revenues for redox flow batteries, 2018-2034, by market (Billions USD). 276
Figure 85. 24M battery. 283
Figure 86. AC biode prototype. 285
Figure 87. Schematic diagram of liquid metal battery operation. 295
Figure 88. 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). 296
Figure 89. Amprius battery products. 298
Figure 90. All-polymer battery schematic. 301
Figure 91. All Polymer Battery Module. 301
Figure 92. Resin current collector. 302
Figure 93. Ateios thin-film, printed battery. 304
Figure 94. The structure of aluminum-sulfur battery from Avanti Battery. 307
Figure 95. Containerized NAS® batteries. 309
Figure 96. 3D printed lithium-ion battery. 314
Figure 97. Blue Solution module. 316
Figure 98. TempTraq wearable patch. 317
איור 99. סכמטי של כור מיטה נוזלית המסוגל להגדיל את הדור של SWNTs באמצעות תהליך CoMoCAT. 335
Figure 100. Cymbet EnerChip™ 340
Figure 101. E-magy nano sponge structure. 348
Figure 102. Enerpoly zinc-ion battery. 349
Figure 103. SoftBattery®. 350
Figure 104. ASSB All-Solid-State Battery by EGI 300 Wh/kg. 352
Figure 105. Roll-to-roll equipment working with ultrathin steel substrate. 354
Figure 106. 40 Ah battery cell. 359
Figure 107. FDK Corp battery. 363
Figure 108. 2D paper batteries. 371
Figure 109. 3D Custom Format paper batteries. 371
Figure 110. Fuji carbon nanotube products. 372
Figure 111. Gelion Endure battery. 375
Figure 112. Portable desalination plant. 375
Figure 113. Grepow flexible battery. 387
Figure 114. HPB solid-state battery. 393
Figure 115. HiNa Battery pack for EV. 395
Figure 116. JAC demo EV powered by a HiNa Na-ion battery. 395
Figure 117. Nanofiber Nonwoven Fabrics from Hirose. 396
Figure 118. Hitachi Zosen solid-state battery. 397
Figure 119. Ilika solid-state batteries. 401
Figure 120. ZincPoly™ technology. 402
Figure 121. TAeTTOOz printable battery materials. 406
Figure 122. Ionic Materials battery cell. 410
Figure 123. Schematic of Ion Storage Systems solid-state battery structure. 411
Figure 124. ITEN micro batteries. 412
Figure 125. Kite Rise’s A-sample sodium-ion battery module. 420
Figure 126. LiBEST flexible battery. 426
Figure 127. Li-FUN sodium-ion battery cells. 429
Figure 128. LiNa Energy battery. 431
Figure 129. 3D solid-state thin-film battery technology. 433
Figure 130. Lyten batteries. 436
איור 131. תהליך ייצור Cellulomix. 439
איור 132. Nanobase לעומת מוצרים קונבנציונליים. 439
איור 133. סוללת Nanotech Energy. 449
איור 134. קונספט של אופנוע חשמלי המופעל על ידי סוללה היברידית. 452
Figure 135. NBD battery. 454
איור 136. איור סכמטי של מערכת תלת קאמרית לייצור SWCNH. 455
איור 137. תמונות TEM של ננומברשת פחמן. 456
Figure 138. EnerCerachip. 460
Figure 139. Cambrian battery. 471
Figure 140. Printed battery. 475
Figure 141. Prieto Foam-Based 3D Battery. 477
Figure 142. Printed Energy flexible battery. 480
Figure 143. ProLogium solid-state battery. 482
Figure 144. QingTao solid-state batteries. 484
Figure 145. Schematic of the quinone flow battery. 486
Figure 146. Sakuú Corporation 3Ah Lithium Metal Solid-state Battery. 489
Figure 147. Salgenx S3000 seawater flow battery. 491
Figure 148. Samsung SDI’s sixth-generation prismatic batteries. 493
Figure 149. SES Apollo batteries. 498
Figure 150. Sionic Energy battery cell. 505
Figure 151. Solid Power battery pouch cell. 507
איור 152. חומרי סוללת ליגנין של Stora Enso. 510
Figure 153.TeraWatt Technology solid-state battery 517
Figure 154. Zeta Energy 20 Ah cell. 534
Figure 155. Zoolnasm batteries. 535