Nanocellulose‐Derived Hierarchical Carbon Framework‐Supported P‐Doped MoO <sub>2</sub> Nanoparticles for Optimizing Redox Kinetics in Lithium–Sulfur Batteries
Mengjiao Shi, Xue Han, Wen Qu, Meihui Jiang, Qing Li, Feng Jiang, Xiang Xu, Shinsuke Ifuku, Chunlei Zhang, Chao Wang, Junfeng Hu, Liansheng Yang, Yuyu Lin, Haipeng Yu, Shouxin Liu, Jian Li, Yiqiang Wu, Wenshuai Chen
Abstract
Abstract The integration of nanocatalysts into the separators of lithium–sulfur batteries (LSBs) boosts the polysulfide conversion efficiency. However, the aggregation of catalyst nanoparticles diminishes the active surface area. Moreover, densely packed catalyst‐modified layers often hinder ion transport rates and impede access to the catalytic sites. To overcome these challenges, a strategy is reported for modifying commercial separators, using wood nanocellulose as a building block to construct hierarchical P‐doped MoO 2−x nanoparticles anchored on N, P co‐doped porous carbon (P‐MoO 2−x /NPC). The web‐like entangled nanocellulose forms a framework for the in situ polymerization of polyaniline, providing abundant anchoring sites for MoO 2 nanoparticles. The addition of P atoms optimizes the d‐band center of MoO 2 and enhances the catalytic activity of polysulfide conversion. The LSBs assembled using a P‐MoO 2−x /NPC coated polypropylene separator display an initial discharge capacity of 1621 mAh g −1 and rate performance of 774 mAh g −1 at 5 C. Even with a sulfur loading of 8.1 mg cm −2 and lean electrolyte conditions, the cell achieves an initial areal capacity of 11.3 mAh cm −2 at 0.1 C. This work provides a biopolymer nanofiber solution for constructing LSB separators with advanced electrochemical reactivity.