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1. | EXECUTIVE SUMMARY |
1.1. | Trends in the Li-ion market |
1.2. | Li-ion value chain |
1.3. | Li-ion market - regional overview |
1.4. | Li-ion market players |
1.5. | Cell capacity expansions outlook |
1.6. | Li-ion graphite anode market overview |
1.7. | Cathode market overview |
1.8. | Cathode production capacity outlook |
1.9. | Key technology developments |
1.10. | Li-ion timeline - technology and performance |
1.11. | Li-ion timeline commentary |
1.12. | Are there alternatives to Li-ion? |
1.13. | Battery technology readiness level snapshot |
1.14. | Impact of material price volatility |
1.15. | Raw material uncertainty |
1.16. | Policy and the Li-ion battery market |
1.17. | Electric vehicle policy |
1.18. | Impact of EV policy |
1.19. | Li-ion anode forecast, GWh |
1.20. | Cathode outlook |
1.21. | Li-ion forecast overview (GWh, $B) |
2. | INTRODUCTION |
2.1. | Importance of Li-ion |
2.2. | What is a Li-ion battery? |
2.3. | Lithium battery chemistries |
2.4. | Types of lithium battery |
2.5. | Why lithium? |
2.6. | Primary lithium batteries |
2.7. | Ragone plots |
2.8. | More than one type of Li-ion battery |
2.9. | Commercial anodes - graphite |
2.10. | The battery trilemma |
2.11. | Battery wish list |
2.12. | Why can't you just fast charge? |
2.13. | Rate limiting factors at the material level |
2.14. | Fast charge design hierarchy |
2.15. | Electrochemistry definitions 1 |
2.16. | Electrochemistry definitions 2 |
2.17. | Useful charts for performance comparison |
3. | ANODES |
3.1. | Overview |
3.1.1. | Anode materials |
3.1.2. | Introduction to graphite |
3.1.3. | Natural graphite for LIBs |
3.1.4. | Coated spherical purified graphite (CSPG) |
3.1.5. | Synthetic/artificial graphite production |
3.1.6. | Natural or synthetic graphite in Li-ion batteries? |
3.1.7. | Synthetic/artificial vs natural graphite |
3.1.8. | Impact of graphite choice on cost |
3.1.9. | Performance of synthetic and natural graphite |
3.1.10. | Synthetic vs natural graphite overview |
3.1.11. | Synthetic vs natural graphite conclusions |
3.1.12. | Artificial/synthetic and natural graphite market split |
3.1.13. | Graphite outlook |
3.1.14. | Suppliers of active graphite material |
3.1.15. | Graphite anode market shares |
3.1.16. | Graphite anode market concentration |
3.1.17. | Geographic breakdown of graphite anode suppliers |
3.1.18. | Expansions in graphite production |
3.1.19. | New entrants in graphite anodes |
3.2. | Silicon |
3.2.1. | The promise of silicon |
3.2.2. | Value proposition of high silicon content anodes |
3.2.3. | The reality of silicon |
3.2.4. | Alloy anode materials |
3.2.5. | Comparing silicon - a high-level overview |
3.2.6. | How much can silicon improve energy density? |
3.2.7. | Cost reductions from silicon |
3.2.8. | Current silicon use |
3.2.9. | Silicon use in EVs |
3.2.10. | Silicon and LFP |
3.2.11. | Commercial silicon anode production |
3.2.12. | Commercial silicon anode production |
3.2.13. | Commercial silicon anodes |
3.2.14. | Commercial silicon anodes |
3.2.15. | Will silicon content increase steadily? |
3.2.16. | Start-ups developing silicon anode solutions |
3.2.17. | Regional Si-anode activity |
3.2.18. | Money in silicon anode start-ups |
3.2.19. | Silicon anode value chain |
3.2.20. | Li-ion anode forecast, GWh |
4. | CATHODES |
4.1. | Cathode technology |
4.1.1. | Cathode recap |
4.1.2. | Cathode materials - LCO and LFP |
4.1.3. | Cathode materials - NMC, NCA and LMO |
4.1.4. | Cathode performance comparison |
4.1.5. | Understanding layered oxide cathodes |
4.1.6. | Why LCO for consumer devices? |
4.1.7. | Cathode powder synthesis (NMC) |
4.1.8. | Cathode development |
4.1.9. | Complexity of cathode chemistry |
4.1.10. | NMC development - from 111 to 811 |
4.1.11. | Cathode materials - NCA |
4.1.12. | Stabilising high-nickel NMC |
4.1.13. | Cathode concentration gradient |
4.1.14. | Protective coatings |
4.1.15. | High nickel cathode stabilisation |
4.1.16. | Protective coatings |
4.1.17. | Single crystal NCA cathode |
4.1.18. | LFP vs NMC |
4.1.19. | LMFP cathodes |
4.1.20. | LMFP commercialisation |
4.1.21. | Future cathode possibilities |
4.1.22. | High manganese cathodes |
4.1.23. | NCMA |
4.1.24. | Beyond metal percentages |
4.1.25. | Manganese rich cathodes |
4.1.26. | High-Ni, High-Mn cathodes |
4.1.27. | High voltage cathodes - LNMO |
4.1.28. | Future cathode prospects |
4.1.29. | Future NMC/NCM - Umicore |
4.1.30. | Patent litigation over NMC/NCM - Umicore vs. BASF |
4.1.31. | Patent litigation over NMC/NCM - Umicore vs. BASF |
4.1.32. | LFP IP |
4.1.33. | Cathode comparisons - overview |
4.1.34. | Players developing next-gen cathodes |
4.1.35. | Cathode performance comparison |
4.1.36. | Chemistry energy density comparison |
4.1.37. | Comparing commercial cell chemistries |
4.1.38. | Impact of material price volatility |
4.1.39. | Impact of material price |
4.1.40. | Impact of lithium price increase on cell material cost |
4.1.41. | Cathode cost breakdown |
4.1.42. | Cathode price fluctuations |
4.1.43. | Cathode cost trend analysis |
4.1.44. | Cathode outlook - which chemistries will be used? 1 |
4.1.45. | Cathode outlook - which chemistries will be used? 2 |
4.1.46. | Cathode suitability |
4.1.47. | LFP adoption in electric vehicles |
4.2. | Cathode market and forecasts |
4.2.1. | Cathode market overview |
4.2.2. | Cathode player manufacturing capacities |
4.2.3. | Cathode manufacturer market share |
4.2.4. | Geographical control of cathode production |
4.2.5. | Geographical breakdown of cathode production |
4.2.6. | Geographical breakdown of cathode capacity |
4.2.7. | Chemistry production spread |
4.2.8. | LFP cathode production dominated by China |
4.2.9. | New entrants |
4.2.10. | Future production capacity outlook |
4.2.11. | Future production capacity outlook by chemistry |
4.2.12. | Future cathode production capacity outlook by chemistry |
4.2.13. | Cathode shares in battery electric cars |
4.2.14. | BEV market by cathode |
4.2.15. | BEV cathode share by region |
4.2.16. | Global cathode market share trend |
4.2.17. | Cathode outlook |
4.2.18. | Cathode outlook - annotated |
4.2.19. | Li-ion electronics market by cathode, GWh |
4.2.20. | Li-ion market by cathode, GWh |
5. | INACTIVE MATERIALS |
5.1. | Binders and conductive additives |
5.1.1. | Binders |
5.1.2. | Binders - aqueous vs non-aqueous |
5.1.3. | Conductive agents |
5.1.4. | Results showing impact of CNT use in Li-ion electrodes |
5.1.5. | Improved performance at higher C-rate |
5.1.6. | Thicker electrodes enabled by CNT mechanical performance |
5.1.7. | Significance of dispersion in energy storage |
5.1.8. | Production capacity of CNTs globally |
5.1.9. | Introduction to Li-ion electrolytes |
5.1.10. | Electrolyte decomposition |
5.1.11. | Electrolyte additives 1 |
5.1.12. | Electrolyte additives 2 |
5.1.13. | Electrolyte additives 3 |
5.1.14. | Developments for the "million mile" battery |
5.1.15. | Electrolyte patent topic comparisons - key battery players |
5.1.16. | Electrolyte patent topic comparisons - key electrolyte players |
5.1.17. | Electrolyte technology overview |
5.1.18. | Electrolyte value chain |
5.1.19. | Electrolyte manufacturers |
5.1.20. | Electrolyte market |
5.1.21. | Electrolyte market by region |
5.1.22. | Electrolyte suppliers |
5.2. | Separators |
5.2.1. | Introduction to Separators |
5.2.2. | Separator manufacturing |
5.2.3. | Polyolefin separators |
5.2.4. | Wet and dry separators |
5.2.5. | Dry and wet separators and specifications |
5.2.6. | Product specification examples |
5.2.7. | Separator coatings |
5.2.8. | Innovation in separators |
5.2.9. | Innovation in separators |
5.2.10. | Li-ion separator market |
5.2.11. | Key separator players |
5.2.12. | Separator market by region |
5.2.13. | Future separator production capacity |
5.3. | Solid electrolytes |
5.3.1. | What is a solid-state battery? |
5.3.2. | Drivers for solid-state and silicon |
5.3.3. | Solid-state electrolytes |
5.3.4. | Partnerships and investors - solid-state and silicon |
5.3.5. | Potential disruptors to conventional Li-ion |
5.3.6. | Cell chemistry comparison - quantitative |
5.4. | Current collectors |
5.4.1. | Where are the current collectors in a Li-ion battery cell? |
5.4.2. | Current collector materials |
5.4.3. | Copper foil production |
5.4.4. | Current collectors |
5.4.5. | Decreasing foil thickness |
5.4.6. | Trends in copper foil thickness |
5.4.7. | Mesh current collectors |
5.4.8. | Perforated foils |
5.4.9. | Plastic current collectors |
5.4.10. | Key copper foil manufacturers |
5.4.11. | Li-ion copper foil market |
6. | CELL MANUFACTURING |
6.1. | Overview |
6.1.1. | Cell production outline |
6.1.2. | Power demand of LIB production |
6.1.3. | Cell production |
6.1.4. | The need for a dry room |
6.1.5. | Electrode slurry mixing |
6.1.6. | Dry-electrode processing |
6.1.7. | Benefits of dry electrode manufacturing |
6.1.8. | Dry vs aqueous electrode manufacturing |
6.1.9. | Formation cycling |
6.1.10. | Areas for improvement in cell production |
6.1.11. | How will cell manufacturing start-ups compete? |
6.2. | Cell manufacturers and expansions |
6.2.1. | Cell manufacturer capacity |
6.2.2. | Large players dominate cell production |
6.2.3. | Battery manufacturer splits |
6.2.4. | Electric car (BEV + PHEV) market by battery manufacturer |
6.2.5. | Electric car battery (BEV + PHEV) manufacturer shares |
6.2.6. | Electric car battery manufacturer market |
6.2.7. | Electric car (BEV + PHEV) battery manufacturer market by region |
6.2.8. | Electric car battery manufacturer market by region |
6.2.9. | How long to build a Gigafactory? |
6.2.10. | How much to build a Gigafactory? |
6.2.11. | Gigafactory expansions |
6.2.12. | Gigafactory expansion plans |
6.2.13. | Cell capacity expansions - Europe |
6.2.14. | Cell capacity expansion - North America |
6.2.15. | Cell capacity expansion - Asia |
6.2.16. | Cell capacity expansions outlook |
6.2.17. | Cell production capacity-demand balances |
6.2.18. | Cell capacity expansions data |
7. | COST ANALYSIS AND FORECASTS |
7.1. | Commodity price volatility |
7.2. | Impact of material price |
7.3. | Cell cost analysis |
7.4. | Cost breakdown |
7.5. | How low can cell costs go? |
7.6. | Historic average cell price |
7.7. | Historic energy storage cost reduction |
7.8. | LIB cell price forecast methodology |
7.9. | Cell price forecast |
7.10. | BEV car pack price |
8. | MODULES AND PACKS |
8.1. | Commercial battery packaging technologies |
8.2. | Automotive format choices |
8.3. | Comparison of commercial cell formats |
8.4. | 4680 cylindrical cells |
8.5. | Li-ion Batteries: From Cell to Pack |
8.6. | Pack design |
8.7. | Battery KPIs for EVs |
8.8. | Henkel's Battery Pack Materials |
8.9. | DuPont's Battery Pack Materials |
8.10. | Lightweighting Battery Enclosures |
8.11. | Lightweighting - Voltabox expanded plastic foam |
8.12. | Latest Composite Battery Enclosures |
8.13. | Towards Composite Enclosures? |
8.14. | Continental Structural Plastics - Honeycomb Technology |
8.15. | Battery Enclosure Materials Summary |
8.16. | Modular pack designs |
8.17. | Ultium BMS |
8.18. | BYD Blade battery |
8.19. | BYD battery design |
8.20. | CATL Cell to Pack |
8.21. | Module and pack manufacturing process |
8.22. | Non-car battery pack manufacturing |
8.23. | Differences in design |
8.24. | Battery pack comparison |
8.25. | Battery module/pack comparison |
9. | APPLICATIONS AND MARKETS |
9.1. | Power range for electronic and electrical devices |
9.2. | Application battery priorities |
9.3. | Electric Vehicle Terms |
9.4. | COP 26 transport targets |
9.5. | Battery electric cars |
9.6. | Hybrid electric vehicles |
9.7. | Passenger Car Market |
9.8. | Notable players for solid-state EV battery technology |
9.9. | Notable players for silicon EV battery technology |
9.10. | Solid-state and silicon timeline |
9.11. | Other Vehicle Categories |
9.12. | Electric Buses: Market History |
9.13. | Electric light commercial vehicles |
9.14. | Electric medium and heavy duty trucks |
9.15. | Two- and three-wheelers |
9.16. | Electronic devices - key applications |
9.17. | Consumer electronics |
9.18. | Power tools and appliances |
9.19. | Consumer electronics - battery to device price ratios |
9.20. | Stationary storage |
10. | FORECASTS |
10.1. | Li-ion forecast, by application (GWh) |
10.2. | Li-ion forecast, by application, tables |
10.3. | Li-ion forecast, $ billion |
10.4. | Li-ion forecasts, by application (GWh) |
10.5. | Li-ion BEV forecast by cathode (GWh) |
10.6. | Li-ion forecast, electric vehicles (GWh) |
10.7. | Li-ion forecasts, electronics (GWh) |
10.8. | Li-ion market by cathode, GWh |
10.9. | Cathode outlook |
10.10. | Li-ion anode forecast, GWh |
11. | COMPANY PROFILES |
11.1. | CATL |
11.2. | LG Energy Solution |
11.3. | EcoPro BM |
11.4. | Posco Chemical |
11.5. | Tinci Materials |
11.6. | SK Innovation (SK On) |
11.7. | Nano One Materials |
11.8. | Group14 Technologies |
11.9. | Toshiba (LTO Batteries) |
11.10. | Birla Carbon |
11.11. | CENS Materials |
Slides | 338 |
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Forecasts to | 2033 |
ISBN | 9781915514264 |