Open Science Repository – Primary Research Data Hub

Primary Research Data Hub is Atomfair LLC’s open science repository for original, company-owned research, testing, and technical analysis. This hub brings together primary datasets, electrochemical evaluations, materials-performance studies, and applied engineering insights generated through Atomfair’s own research programs.

We are beginning with advanced battery systems because batteries sit at the center of today’s materials, energy, and manufacturing challenges. The current repository focuses on high-voltage sodium-ion and lithium-ion systems, electrolyte and interphase stability, dry electrode processing, silicon-carbon anodes, high-nickel cathodes, LCO, LMR, NFPP, Prussian Blue materials, pouch-cell cycling, cycle-life tradeoffs, and practical limits observed in real testing environments.

This is only the starting point. Atomfair is building this repository as a long-term open science initiative: a growing technical library where our proprietary research, test results, and analysis can help researchers, engineers, institutions, and industry teams evaluate materials more transparently and accelerate scientific progress. As our work expands, the repository will grow beyond batteries into broader advanced materials, energy systems, equipment data, and applied laboratory science.

CVD Nano-Silicon Carbon: Breakthrough Engineering for the 80% Silicon Barrier

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Technical overview of CVD nano-silicon carbon for 82% silicon anodes, covering nanoconfinement, electrolyte-stabilized SEI behavior, and pouch-cell cycling data.

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Next-Gen Battery Insights | 09: Taming Ni90—Extreme Stability in 4.3V High-Voltage Systems

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Industrial pouch-cell evaluation of Ni90||graphite at 4.3V shows how customized electrolytes and CEI control improve cycling stability and high-loading performance.

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Next-Gen Battery Insights | 10: The 460 Wh/kg Gamble—Can Perfluorinated Electrolytes Solve the LMR High-Voltage Crisis?

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Technical analysis of perfluorinated electrolytes for 4.8 V LMR pouch cells, covering CEI formation, oxidative stability, cycle-life limits, and 460 Wh/kg tradeoffs.

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