Battery Safety Summit
Next Generation Advancements for Safe and Efficient Energy Storage System Applications
安全かつ効率的なエネルギー貯蔵システム応用における次世代の進歩
2026年8月12日 - 13日 CDT(米国中部標準時・夏時間)
Wednesday, August 12
12:00 pmRegistration Open
12:50 pmOrganizer's Opening Remarks
SOLID-STATE BATTERY DESIGN AND SAFETY
固体電池の設計と安全性
Liquid, Solid, and Semi-Solid Batteries with Focus on Battery Safety
John Zhang, PhD, CTO/CSO, Polypore International
This presentation will address the safety behavior and underlying mechanisms of SSBs, with direct comparison to liquid-state batteries (LSBs). Testing results show that, during internal shorts in high-energy systems, the severity of fire and explosion follows the order: SSB > LSB. The data indicate a counterintuitive trend-the greater the liquid content in the battery, the safer its behavior under abuse conditions.
Engineered Cathode Chemomechanics Enables Ultra-Low Stack Pressure Solid-State Batteries
Paul V. Braun, PhD, Professor & Grainger Distinguished Chair, Engineering, University of Illinois Urbana Champaign
Stresses resulting from electrode material chemomechanics are strongly coupled to solid electrolyte-electrode interface failures. Such failures are significant barriers to realization of practical Li-metal solid-state batteries (SSBs). We show the importance of cathode chemomechanics at commercially relevant low stack pressures (e.g., <1 MPa). Utilizing these learnings, we build long cycle-life SSBs with practical areal capacity (5 mAh/cm2) operating at less than 1 MPa stack pressure at room temperature.
Safety and Manufacturability of Semi-Solid-State Li-Metal Batteries with Ultra-Thin Anode
Alex Kosyakov, Co-Founder & CEO, Natrion Inc.
Natrion is the manufacturer of Active Separator, a thin, flexible solid-state electrolyte separator for lithium secondary batteries. Natrion will present its latest validation of the performance and safety of semi-solid lithium-metal batteries pairing Active Separator with 5-20 micrometer-thick lithium-metal anodes. This will include cyclability of high-capacity pouch cells at ambient temperatures and pressures (zero clamping) demonstrating 1000+ Wh/L, 400+ Wh/kg energy densities, as well as independent abuse testing results.
Cell Failure Detection
セル故障検出
Identification of Early Signs of Failures in Lithium-Ion Batteries
A comprehensive understanding of the mechanisms that lead to cell failure in lithium-ion batteries is essential for the advancement of global battery sector. Robust detection methodologies are required to identify the onset of failure at early stages. In this study, we employ a combination of electrochemical analysis and advanced characterisation techniques to investigate the electrochemical phenomena occurring within cathodes and anodes. Utilising a three-electrode pouch cell configuration with lithium iron phosphate as the reference electrode, we assessed the electrochemical behaviour of both cathodes and anodes as cells approach unsafe conditions. For detailed characterisation, plasma focused ion beam (PFIB) scanning electron microscopy (SEM) and X-ray photoelectron spectroscopy (HAXPES and XPS) were conducted ex situ on cathode and anode materials. Additionally, operando nuclear magnetic resonance (NMR) spectroscopy was performed to elucidate failure mechanisms under extreme operational scenarios. The results establish a systematic methodology for identifying critical markers indicative of cell safety risks, offering potential for adaptation and implementation across a range of commercially relevant cell formats.
3:00 pmRefreshment Break in the Exhibit Hall with Poster Viewing (Sponsorship Opportunity Available)
3:30 pmSponsored Presentation (Opportunity Available)
OEM & MANUFACTURING PERSPECTIVES ON BATTERY SAFETY
電池の安全性に関するOEMと製造の視点
FEATURED PRESENTATION: An Ounce of Prevention: Formation Data Analysis for Defect Detection at Production Scale
James Salvador, Staff Researcher, Chemical Sciences & Materials Systems Laboratory, General Motors
In gigawatt Li-ion battery plants, cell defects with vanishingly low probability can occur daily. In this talk, we will show automated gas harvesting and analysis hardware solutions for quantification of formation gas-and software solutions for time series formation charge analysis that can enable in situ determination of cell-quality anomalies that could potentially lead to premature failure. These methods leverage existing data streams to improve safety through prevention.
Battery Thermal Propagation Mitigation Strategies across Cell Chemistries & Cell Form Factors
Bhaskara Boddakayala, Global Technical Expert, Battery Safety & Materials, Cell Vent Management, Ford Motor Company
Battery thermal propagation represents one of the most critical safety challenges in modern energy-storage systems, particularly as battery-pack energy densities continue to increase across automotive, stationary storage, and consumer applications. This presentation focuses on analysis and examines current solution trends; compares protection strategies at cell, module, and pack levels; and evaluates chemistry-specific approaches to mitigating thermal-runaway propagation.
5:00 pmWelcome Reception in the Exhibit Hall with Poster Viewing (Sponsorship Opportunity Available)
6:00 pmEvening Tutorial*
Battery Safety and Abuse Tolerance Validation
7:30 pmClose of Day
Thursday, August 13
8:00 amRegistration Open and Morning Coffee
8:20 amOrganizer's Welcome Remarks
THERMAL-RUNAWAY MITIGATION
熱暴走の緩和
Isolating Internal Shorts with Metallized Polymer Current Collectors
Eric Darcy, PhD, former Battery Technical Discipline Lead, NASA-JSC; Private Consultant, Darcy Batt Consulting, LLC
Metallized polymer current collectors for the cathode have been demonstrated to consistently (27 of 27 trials) tolerate nail penetration (shallow or deep) in 21700 cell designs that achieve >250 Wh/kg when coupled with isotropic strength polymer separators and a thermally-stable ceramic coating on the anode active material. Only soft shorts develop and thermal runaway is obviated. High-speed radiography, cell OCV and temperature measurements, and post-test CT images of the nail holes reveal insights into the isolating mechanism. These innovative inert cell features can dramatically improve the safety of the vast majority of Li-ion cell chemistries.
Lithium-ion Battery Fire Suppression for Aircraft Cargo-Compartment Fires
Judy Jeevarajan, PhD, Vice President and Executive Director, Electrochemical Safety Research Institute, UL Research Institutes
Lithium-ion batteries used for portable applications are getting significantly large in terms of energy, and pose fire hazards of concern in the cargo compartments of aircraft. Studies have been carried out that include thermal runaway tests on these batteries ranging from a few tens of Wh to about 350 Wh. Suppressants that include Halon 1301, water, and water additives have been tested to characterize the efficacy of suppression.
Thermal Runaway Risks in Flooded Electric Vehicles: Insights from Submersion Testing and Diagnostics
Tanvir Tanim, Battery R&D Engineer and Group Lead, Energy Storage Technology Group, Idaho National Laboratory
Electric vehicle (EV) battery packs pose safety risks during saltwater submersion, as seen in recent hurricane-related incidents leading to thermal runaway. This study examines pack vulnerabilities through teardowns and full-scale immersion tests, identifying failure modes such as seal weaknesses, component degradation, and pathways to thermal runaway. Results show current immersion standards do not ensure safety under prolonged flooding. Early diagnostic signals were also identified, offering potential early warnings before failure. These findings support improved pack design, early-warning systems, updated standards, and emergency response strategies for saltwater-flooded EVs.
10:00 amSponsored Presentation (Opportunity Available)
10:30 amCoffee Break in the Exhibit Hall with Poster Viewing (Sponsorship Opportunity Available)
Can Sparse Temperature Sensing Reliably Detect Thermal Runaway? Bridging the Gap Between Theory and Commercial Battery Packs
Yatish Patel, PhD, Fellow, Mechanical Engineering, Imperial College London
Battery packs in electric vehicles rely on sparse temperature sensing, often as little as one sensor for every ten cells, yet this limitation is rarely addressed in thermal runaway detection research. This talk evaluates how effective these low-cost temperature measurements are for early fault detection, using a combined modelling and experimental approach. It critically compares temperature-based diagnostics with alternative sensing methods, demonstrating that despite limitations, temperature sensing remains the most viable solution for scalable, cost-constrained battery management systems.
Scaling Early Thermal-Runaway Detection from Cell to EV Module
Loraine Torres-Castro, PhD, Battery Safety Lead, Sandia National Laboratories
Early thermal-runaway detection in scaled electric-vehicle battery systems remains challenging due to sparse sensing and signal averaging across parallel-connected cells. This study experimentally evaluates advanced gas sensors and high-voltage electrochemical impedance spectroscopy in commercial Tesla modules housed in a pack-representative enclosure. Controlled single-cell overheating was used to assess diagnostic response at module scale, addressing the gap between cell-level validation and full-pack implementation.
KEY STANDARDS FOR ENERGY STORAGE
エネルギー貯蔵向け主要規格
Battery Energy Storage Systems: Safety Approaches and Best Practices
How Requirement & Regulations for EV’s and BESS are Converging
1:00 pmEnjoy Lunch on Your Own
ABUSE TOLERANCE, ADVANCED TESTING, AND SIMULATION
不正使用の容認、先端の試験、シミュレーション
Flammability and Safety of Next-Generation Battery Electrolytes: From Liquids to Gels
Mickael Dollé, PhD, Professor, Department of Chemistry, Université de Montréal
Electrolyte flammability is a critical safety and deployment barrier for next-generation batteries. This presentation introduces standardized flash point measurements applied to both aqueous-organic and gel-polymer electrolytes, providing quantitative insight into ignition risks across liquid and quasi-solid systems. By linking flammability to solvent composition, solvation structure, and polymer-solvent interactions through spectroscopic and data-driven analysis, we highlight key design rules to mitigate volatility and combustion risk. These results offer actionable guidance for industrial development of safer, high-performance electrolyte formulations.
Performance of Highly Durable Zinc Secondary Batteries Using SOE Technology
Masatsugu Morimitsu, Dr.Eng., Professor, Department of Science of Environment and Mathematical Modeling, Doshisha University; CTO, HEW NEXUS Co., Ltd.
This talk presents the charge-discharge cycling performance of laminated zinc rechargeable batteries using SoE (segmentation of electrolyte) technology for electric vehicles (EVs) and stationary energy-storage applications. This technology suppresses zinc dendrite formation during charging, enabling high durability with stable voltages and high voltage efficiency.
How Safe Are Solid-State Batteries? Identifying Hazards with a Bottom-up Approach
Nathan Johnson, PhD, Senior Member of Technical Staff, Sandia National Laboratories
This talk examines safety considerations in solid-state batteries using a bottom-up approach. By analyzing material behavior and interface interactions, we identify potential failure mechanisms and highlight emerging insights that challenge assumptions about the inherent safety of solid-state systems.
4:00 pmClose of Summit
* 不測の事態により、事前の予告なしにプログラムが変更される場合があります。
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