Li-ion Batteries and Battery Management Systems for Electric Vehicles 2024-2034

1. EXECUTIVE SUMMARY

1.1. Key takeaways (1)

1.2. Key takeaways (2)

1.3. Major EV categories

1.4. Major EV categories

1.5. Future role for battery pack manufacturers

1.6. Remarks on battery manufacturers

1.7. Battery pack comparison

1.8. Turnkey battery pack performance comparison

1.9. Chemistry choices in turnkey EV packs

1.10. Turnkey battery design choices -cell form factor and cooling

1.11. Pack manufacturers

1.12. Trends in battery management systems

1.13. BMS patent landscape

1.14. BMS players

1.15. Innovations in BMS

1.16. Advanced BMS activity

1.17. BMS solutions for fast charging

1.18. Improvements to battery performance from BMS development

1.19. Regional BEV chemistry trends

1.20. EV cell supplier share

1.21. BEV cell form factors

1.22. BEV cell energy density trends

1.23. Development trends to LIB technology

1.24. Technology roadmap

1.25. Li-ion market demand shifts

1.26. BEV car pack price

1.27. EV Li-ion demand (GWh)

1.28. EV Li-ion battery market (US$B)

2. INTRODUCTION

2.1. Electric Vehicles: Basic Principle

2.2. Electric Vehicle Terms

2.3. Drivetrain Specifications

2.4. Parallel and Series Hybrids: Explained

2.5. What are the Barriers for Electric Vehicles?

2.6. What are the Barriers for Electric Vehicles?

2.7. Carbon emissions from electric vehicles

2.8. Policy and the Li-ion battery market

2.9. Electric vehicle policy

2.10. Impact of EV policy

2.11. Automaker EV Targets

3. LI-ION CELL TECHNOLOGY

3.1. Li-ion cells (cathodes, anodes, form factor, performance trends)

3.1.1. Importance of Li-ion

3.1.2. What is a Li-ion battery?

3.1.3. Lithium battery chemistries

3.1.4. Why lithium-ion?

3.1.5. Types of lithium battery

3.1.6. The Li-ion Supply Chain

3.1.7. Cell production capacity outlook

3.1.8. The Battery Trilemma

3.1.9. Battery wish list

3.1.10. Cathode comparisons – overview

3.1.11. Cathode performance comparison

3.1.12. Chemistry energy density comparison

3.1.13. Suitability of LFP for EVs

3.1.14. Impact of material price increases

3.1.15. Cathode prices

3.1.16. LFP in EVs

3.1.17. Anode comparisons – overview

3.1.18. Anode performance comparison

3.1.19. Anode share

3.1.20. Historic average cell price

3.1.21. How low can cell costs go?

3.1.22. How low can cell costs go?

3.1.23. Cell Types

3.1.24. Automotive format choices

3.1.25. Cell Format Market Share

3.1.26. Cell Format Comparison

3.1.27. Cell sizes

3.1.28. 4680 cylindrical cells

3.1.29. Comparing commercial cell chemistries

3.1.30. Commercial cell specifications

3.1.31. Commercial Li-ion cell performance

3.1.32. EV cell specifications

3.1.33. Increasing BEV battery cell specific energy

3.1.34. Increasing BEV battery cell energy density

3.1.35. Improvements to energy density

3.1.36. Timeline and outlook for Li-ion energy densities

3.1.37. Cycle life requirements for electric vehicles

3.2. Next-generation cell technology

3.2.1. How much can silicon improve energy density?

3.2.2. Current silicon use

3.2.3. Silicon use in EVs

3.2.4. Silicon and LFP

3.2.5. Partnerships

SDGs, Targets, and Indicators Analysis

1. Which SDGs are addressed or connected to the issues highlighted in the article?

• SDG 7: Affordable and Clean Energy
• SDG 9: Industry, Innovation, and Infrastructure
• SDG 11: Sustainable Cities and Communities
• SDG 12: Responsible Consumption and Production
• SDG 13: Climate Action
• SDG 14: Life Below Water
• SDG 15: Life on Land

2. What specific targets under those SDGs can be identified based on the article’s content?

• SDG 7.2: Increase substantially the share of renewable energy in the global energy mix.
• SDG 9.4: Upgrade infrastructure and retrofit industries to make them sustainable.
• SDG 11.2: Provide access to safe, affordable, accessible, and sustainable transport systems for all.
• SDG 12.2: Achieve sustainable management and efficient use of natural resources.
• SDG 13.2: Integrate climate change measures into national policies, strategies, and planning.
• SDG 14.2: Sustainably manage and protect marine and coastal ecosystems to avoid significant adverse impacts.
• SDG 15.2: Promote the implementation of sustainable management of all types of forests.

3. Are there any indicators mentioned or implied in the article that can be used to measure progress towards the identified targets?

Yes, there are indicators mentioned or implied in the article that can be used to measure progress towards the identified targets. These include:

• Share of renewable energy in the global energy mix
• Investments in sustainable infrastructure and industries
• Access to safe and sustainable transport systems
• Efficient use of natural resources
• Integration of climate change measures into policies and planning
• Protection and sustainable management of marine and coastal ecosystems
• Sustainable management of forests

Table: SDGs, Targets, and Indicators

Behold! This splendid article springs forth from the wellspring of knowledge, shaped by a wondrous proprietary AI technology that delved into a vast ocean of data, illuminating the path towards the Sustainable Development Goals. Remember that all rights are reserved by SDG Investors LLC, empowering us to champion progress together.

Source: idtechex.com

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