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Design rules for anion-doped catalysts revealed by p-p-s orbital coupling in Li-S chemistry

Wei Wang, Xinying Wang, Huanhuan Yang, Zhipeng Yu, Weicai Zhang, Haoliang Huang, Zaowen Zhao, Xuerong Zheng, Lifeng Liu, Yida Deng, Yunyong Li

2025Nature Communications9 citationsDOIOpen Access PDF

Abstract

A rational design principle for selecting optimal anion dopants in transition-metal compounds to enhance sulfur redox activity is lacking in Li-S batteries. Herein, we propose an accurate p-p-s orbital electronic coupling descriptor (involving the p-orbitals of anion dopants and anions in transition-metal compounds and the s-orbitals of Li in lithium polysulfides) as a criterion for choosing anion dopants to guide the development of efficient anion-doped Li-S catalysts through machine-learning, theoretical, and experimental validation. We reveal the relationship between the electronic properties of various anion-doped WSe2 and the thermodynamics and kinetics of sulfur redox. Our findings show that moderate p-p-s orbital electronic coupling optimizes polysulfide adsorption, facilitating Li2S nucleation and decomposition, thereby minimizing Gibbs free energy and maximizing catalytic efficiency for sulfur redox. A volcano relationship between the p-p-s coupling strength and catalytic activity is established. The optimal B-WSe2/MXene catalyst achieves a ~ 3 Ah pouch cell with 430 Wh kg−1 specific energy and good cycle life (81.3% capacity retention over 71 cycles). These findings provide a guideline for designing efficient anion-doped Li-S catalysts with moderate p-p-s coupling to enable rapid sulfur catalytic conversion in Li-S batteries. The mechanism of how different anion dopants influence the catalytic performance for sulfur species is currently lacking systematic theoretical studies. Here, an accurate p-p-s electronic coupling descriptor was proposed as a criterion to guide the design of anion-doped Li-S catalysts.

Topics & Concepts

CatalysisDopantSulfurIonNucleationChemistryChemical physicsCoupling (piping)Gibbs free energyComputational chemistryPolysulfideLithium (medication)Materials scienceCatalytic cycleInorganic chemistryThermodynamicsPopulationPerovskite (structure)Oxidative coupling of methanePhysical chemistryElectronic structureMolecular orbitalCombinatorial chemistryAdvanced Battery Materials and TechnologiesInorganic Chemistry and MaterialsMXene and MAX Phase Materials
Design rules for anion-doped catalysts revealed by p-p-s orbital coupling in Li-S chemistry | Litcius