Abstract
Enhancing Li(2)S deposition and oxidation kinetics in lithium-sulfur batteries, especially the potential-limiting step under lean electrolyte, can be effectively achieved by developing conductive catalysts. In this study, by using ZnMoO(4) as precursors, Zn-doped molybdenum carbide microflowers (Zn-Mo(2)C) composed of speared porous sheets are fabricated with a hierarchically ordered structure. Density functional theory calculations indicate that Zn doping shifts the d-band center on Mo atoms in Mo(2)C upward, promotes the elevation of certain antibonding orbitals in Mo─S bonds above the Fermi level, enhances d-p interaction between lithium polysulfides (LiPSs) and catalysts, weakens both S─S and Li─S bonds of LiPSs. Incorporating Zn significantly reduces the Gibbs free energy barrier for the rate-limiting step of the Li(2)S(2) → Li(2)S conversion, from 0.52 eV for Mo(2)C to just 0.05 eV for Zn-doped Mo(2)C. Thus, the synthesized Zn-Mo(2)C demonstrates impressive bifunctional electrocatalytic performance, significantly advancing sulfur reduction and Li(2)S decomposition. Moreover, this modification enhances charge transfer within the Zn-Mo(2)C/LiPSs system, synergistically accelerating the kinetics of Li(2)S(4) to Li(2)S reduction and Li(2)S oxidation. The Zn-Mo(2)C/S cathode demonstrates impressive electrochemical performance, achieves remarkable cycling stability with a minimal capacity decay of 0.021% per cycle over 1000 cycles at 5 C, underscoring its potential for high-energy applications.