Welcome to ATOMFAIR’s Battery Research and Science Hub. This curated educational repository delivers deep-tech insights, peer-reviewed analysis, and fundamental science guides on next-generation energy storage. Explore the core principles driving advanced lithium-ion battery innovations, solid-state engineering, and sodium-ion electrochemistry. From benchmarking high-capacity LIB chemistries to pioneering alternative cell architectures, our guides are designed to accelerate modern laboratory R&D.
Lithium Battery Safety: Material Design & Protection Strategies for Thermal Runaway
Thermal runaway of lithium-ion batteries is a key bottleneck restricting their application in new energy vehicles, large-scale energy storage and other fields — once triggered, it may cause catastrophic consequences such as fire and explosion. The occurrence of thermal runaway is directly related to the performance of the four core materials: separator, electrolyte, cathode, and…
NASICON Solid Electrolytes: LATP/LAGP R&D, Synthesis & Modification
In the wave of solid-state battery technology, NASICON-type solid electrolytes have become core competitors for commercialization due to their excellent air stability, high ionic conductivity and low cost. Among them, LATP (Li₁₊ₓAlₓTi₂₋ₓ(PO₄)₃) and LAGP (Li₁₊ₓAlₓGe₂₋ₓ(PO₄)₃) have attracted much attention from the scientific and industrial communities with their excellent comprehensive performance. However, the traditional R&D model…
Aramid Lithium Battery Separator: Dual Safety Design for Thermal Runaway Prevention
The core risk of lithium battery thermal runaway often stems from the “dereliction of duty” of the separator — traditional polyolefin separators have limited heat resistance, and it is difficult to balance the shutdown temperature and rupture temperature. They either fail to timely block ion transport in the early stage of thermal runaway, or break…