Symposium FE
Next Generation Electrochemical Energy Storage Materials and Systems
Convener:
Bruce S. DUNN, University of California, Los Angeles, USA
Members:
Palani BALAYA, National University of Singapore, Singapore
Torsten BREZESINSKI, Karlsruhe Institute of Technology, Germany
Thierry BROUSSE, Université de Nantes, France
Dongliang CHAO, Fudan University, China
Zheng CHEN, University of California, San Diego, USA
Xinliang FENG, TU Dresden, Germany
Maximilian FICHTNER, Helmholtz-Institute Ulm (HIU), Germany
Diana GOLODNITSKY, Tel Aviv University, Israel
Steve G. GREENBAUM, City University of New York, USA
Arumugam MANTHIRAM, The University of Texas at Austin, USA
Petr NOVAK, Technical University of Braunschweig, Germany
Stefano PASSERINI, Karlsruhe Institute of Technology, Germany
Volker PRESSER, Saarland University, Germany
Patrice SIMON, University Paul Sabatier, France
Wataru SUGIMOTO, Shinshu University, Japan
Martin WINTER, Universitaet Muenster, Germany
Nae-Lih WU, National Taiwan University, Taiwan
Atsuo YAMADA, The University of Tokyo, Japan
Bruce S. DUNN, University of California, Los Angeles, USA
Members:
Palani BALAYA, National University of Singapore, Singapore
Torsten BREZESINSKI, Karlsruhe Institute of Technology, Germany
Thierry BROUSSE, Université de Nantes, France
Dongliang CHAO, Fudan University, China
Zheng CHEN, University of California, San Diego, USA
Xinliang FENG, TU Dresden, Germany
Maximilian FICHTNER, Helmholtz-Institute Ulm (HIU), Germany
Diana GOLODNITSKY, Tel Aviv University, Israel
Steve G. GREENBAUM, City University of New York, USA
Arumugam MANTHIRAM, The University of Texas at Austin, USA
Petr NOVAK, Technical University of Braunschweig, Germany
Stefano PASSERINI, Karlsruhe Institute of Technology, Germany
Volker PRESSER, Saarland University, Germany
Patrice SIMON, University Paul Sabatier, France
Wataru SUGIMOTO, Shinshu University, Japan
Martin WINTER, Universitaet Muenster, Germany
Nae-Lih WU, National Taiwan University, Taiwan
Atsuo YAMADA, The University of Tokyo, Japan
The list of Invited Speakers will be available at the end of July 2025
Electrochemical energy storage has witnessed extraordinary growth over the past two decades as the need for energy storage solutions now extends from small sizes for mobile electronics to medium sizes for transportation to large sizes for grid storage. The demand to improve materials and energy storage is expected to continue unabated in order to implement renewable energy sources and achieve the goal of net zero carbon emissions.
This symposium addresses the energy storage challenge by focusing on new and emerging materials science and engineering directions which are expected to enhance energy storage characteristics, increase stability, improve safety, and reduce the cost of electrochemical energy storage technologies. The most promising and latest solutions for the efficient storage of electrical energy will be emphasized as we intend to cover the most recent materials developments for high energy and high power rechargeable batteries, high rate energy storage, electrochemical capacitors, hybrid devices, and related technologies. Highlighted areas include the design and synthesis of new electrode and electrolyte materials for Li-ion, Na-ion, K-ion and solid-state batteries, redox-based electrochemical capacitors, advanced characterization methodologies including in situ techniques, and computational analysis to predict material behavior and guide the design of new materials.
The infusion of new approaches is essential if improved materials for electrochemical energy-storage solutions for transportation, grid energy storage, and portable devices are to be achieved. Papers pertaining to the discovery of novel materials via AI/ML and the integration of theory and simulation are an integral part of this symposium as are advances in electrode and electrolyte materials, the development of new cell chemistries and configurations, novel electrode architectures and advanced characterization including in-operando approaches. Taken together, these topics represent the basis for the development of next generation energy storage materials and systems.
This symposium addresses the energy storage challenge by focusing on new and emerging materials science and engineering directions which are expected to enhance energy storage characteristics, increase stability, improve safety, and reduce the cost of electrochemical energy storage technologies. The most promising and latest solutions for the efficient storage of electrical energy will be emphasized as we intend to cover the most recent materials developments for high energy and high power rechargeable batteries, high rate energy storage, electrochemical capacitors, hybrid devices, and related technologies. Highlighted areas include the design and synthesis of new electrode and electrolyte materials for Li-ion, Na-ion, K-ion and solid-state batteries, redox-based electrochemical capacitors, advanced characterization methodologies including in situ techniques, and computational analysis to predict material behavior and guide the design of new materials.
The infusion of new approaches is essential if improved materials for electrochemical energy-storage solutions for transportation, grid energy storage, and portable devices are to be achieved. Papers pertaining to the discovery of novel materials via AI/ML and the integration of theory and simulation are an integral part of this symposium as are advances in electrode and electrolyte materials, the development of new cell chemistries and configurations, novel electrode architectures and advanced characterization including in-operando approaches. Taken together, these topics represent the basis for the development of next generation energy storage materials and systems.
Session Topics
FE-1 Batteries
- Rechargeable batteries: anodes, cathodes, and electrolytes
- Cell chemistries: Li-ion, Li-S, Li-air, Na-ion, Mg-ion, Al-ion, all solid-state, redox flow, etc.
- Bulk, surface, and interfacial characterizations
- Computational modeling
- Novel Materials via AI/ML
- Cell design
- Application engineering
FE-2 Supercapacitors
- Supercapacitors
- Pseudocapacitors and hybrid devices
- Electrodes and electrolytes
- Cell design