Chemical Etching of Nanoporous Al Foil for Enhancing the Stability of LiFeMnPO 4 Cathodes

This work addresses critical interfacial instability in lithium manganese iron phosphate (LMFP) cathodes by developing a nanoporous aluminum current collector (NP‐Al) via controlled chemical etching. Characterization reveals a uniform 50‐nm pore architecture (SEM/AFM) that enhances surface roughness by 210% and forms a protective Al 2 O 3 layer (XPS), while preserving bulk conductivity (XRD). Electrochemical validation demonstrates that NP‐Al significantly outperforms conventional Al foil: LMFP/NP‐Al achieves 84% capacity retention after 300 cycles at 1C (vs. 66% for LMFP/Al) and triples peel strength (1.28 vs. 0.42 kN/m). These performance improvements are correlated with three synergistic effects: (1) mechanical interlocking potentially mitigating active material delamination, (2) 35% lower charge transfer resistance (EIS: 206.6 Ω vs. 318.1 Ω) supporting 415% higher capacity at 10 C, and (3) electrolyte‐wetting optimization (contact angle: 31.9° vs. 46.4° in NMP). These innovations mitigate the interplay between adhesion and degradation in high‐energy cathodes, positioning nanoporous collectors as promising enablers for durable lithium‐ion batteries.