About this Research Topic
Advanced batteries are pivotal to the advancement of electric vehicles, smart grids, portable electronics, and other emerging applications. As batteries become ubiquitous in daily life, significant attention is now directed toward rapid charging, safe operation, health monitoring, internal state analysis, life prediction, and endurance. However, there exist research gaps concerning the safety, reliability, efficiency, cost-effectiveness, and lifespan of battery systems when integrated with new materials, power electronics, system control, artificial intelligence, and other technologies.
The global transition from internal combustion engine vehicles to Electric Vehicles (EVs) stands as a pivotal initiative in combating climate change. Cities, suburbs, and towns have seen a significant rise in new EV adoption. Furthermore, municipalities and townships are setting ambitious climate targets, aiming for complete decarbonization by 2050 or earlier. Yet, beyond EVs, the electrification of public transportation, heating, and cooling presents a distinct challenge in urban decarbonization efforts, necessitating a shift away from fossil fuels amidst surging energy demands. Battery systems hold a crucial role in this context. Topics such as reliability, resilience support, procurement of ancillary services, long-term monitoring using digital twins, safety standards, lifetime capacity management, and optimal energy are likely to attract the attention of researchers worldwide.
This Research Topic aims to consolidate contributions from researchers specializing in advanced materials, modeling, monitoring, control, optimization, and management of batteries in urban environments facing stringent decarbonization goals. We invite original research articles, review articles, and short communications from academia and industry experts. Integration into urban distribution and sub-transmission grids are critical research areas. Despite their significant impact, these aspects of battery storage systems have received minimal attention.
The topics of this Research Topic include but are not limited to the following items:
1. Equivalent electrical and thermal models of battery packs/cells
2. Advanced materials for high energy density batteries
3. Innovative electrode and cell designs for enhanced performance
4. Prognostics and diagnostics for battery faults
5. Estimation and prediction of remaining useful life
6. Recycling and repurposing of batteries
7. Non-destructive analysis and high-temperature warnings for batteries
8. Monitoring battery status and extracting parameters during wireless EV charging
9. Efficient strategies for fast charging of electric vehicle batteries
10. Data-driven methods for extracting battery parameters, predicting lifetime, and estimating capacity fade
11. Energy management frameworks for battery swapping stations
12. Cybersecurity considerations for battery management systems
13. Application of Artificial Intelligence in load forecasting and optimal scheduling of charging stations
14. Multi-objective optimization strategies for batteries
15. Batteries for electric vehicles and emerging applications
16. Overview paper on challenges and advancements in battery technology
The global transition from internal combustion engine vehicles to Electric Vehicles (EVs) stands as a pivotal initiative in combating climate change. Cities, suburbs, and towns have seen a significant rise in new EV adoption. Furthermore, municipalities and townships are setting ambitious climate targets, aiming for complete decarbonization by 2050 or earlier. Yet, beyond EVs, the electrification of public transportation, heating, and cooling presents a distinct challenge in urban decarbonization efforts, necessitating a shift away from fossil fuels amidst surging energy demands. Battery systems hold a crucial role in this context. Topics such as reliability, resilience support, procurement of ancillary services, long-term monitoring using digital twins, safety standards, lifetime capacity management, and optimal energy are likely to attract the attention of researchers worldwide.
This Research Topic aims to consolidate contributions from researchers specializing in advanced materials, modeling, monitoring, control, optimization, and management of batteries in urban environments facing stringent decarbonization goals. We invite original research articles, review articles, and short communications from academia and industry experts. Integration into urban distribution and sub-transmission grids are critical research areas. Despite their significant impact, these aspects of battery storage systems have received minimal attention.
The topics of this Research Topic include but are not limited to the following items:
1. Equivalent electrical and thermal models of battery packs/cells
2. Advanced materials for high energy density batteries
3. Innovative electrode and cell designs for enhanced performance
4. Prognostics and diagnostics for battery faults
5. Estimation and prediction of remaining useful life
6. Recycling and repurposing of batteries
7. Non-destructive analysis and high-temperature warnings for batteries
8. Monitoring battery status and extracting parameters during wireless EV charging
9. Efficient strategies for fast charging of electric vehicle batteries
10. Data-driven methods for extracting battery parameters, predicting lifetime, and estimating capacity fade
11. Energy management frameworks for battery swapping stations
12. Cybersecurity considerations for battery management systems
13. Application of Artificial Intelligence in load forecasting and optimal scheduling of charging stations
14. Multi-objective optimization strategies for batteries
15. Batteries for electric vehicles and emerging applications
16. Overview paper on challenges and advancements in battery technology
Keywords: Battery modeling, battery control, battery monitoring, battery management, power electronics, power systems, electric vehicles
Important Note: All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.
