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An Electron-Coupled Co-ZrO<sub>2</sub> Nanodot Heterojunction Electrocatalyst with Lewis Acid–Base Site Pairs Enables High Redox Reaction Kinetics of Li–S Batteries

MA Yanyan, Liang Zhang, Shujie Liu, Shuo Chen, Jianyong Yu, Bin Ding, Jianhua Yan

2024ACS Nano26 citationsDOI

Abstract

Using electrocatalysts is effective in solving the slow reaction kinetics of polysulfides in Li–S batteries, but designing stable electrocatalysts with an integrated adsorption-catalysis-desorption system is challenging. Here, we report a stable metal–semiconductor (Co-ZrO 2 ) heterojunction electrocatalyst fabricated by assembling electron-coupled Co-ZrO 2 nanodots into macroporous carbon nanofibers. The Co-ZrO 2 contact causes interfacial electron enrichment and electron transfer from Co to ZrO 2, which creates abundant Lewis-acid sites on Co that can adsorb polysulfides. Simultaneously, the enriched interfacial electrons can activate the S–S bond and boost the catalytic conversion of long-chain polysulfides, while the ZrO 2 with Lewis-base sites facilitate the desorption of short-chain polysulfides from the electrocatalyst. Moreover, the nanodot heterojunctions show great chemical stability and high redox reaction kinetics of polysulfides. Li–S batteries show high discharge capacities of 954.5 mA h·g –1 at 0.5 C with a retention of 84.9% over 200 cycles, and 710.2 mA hg –1 at 1 C with a retention of 98.6% over 200 cycles. This study provides an effective strategy for developing active and durable electrocatalysts for Li–S batteries.

Topics & Concepts

ElectrocatalystRedoxNanodotKineticsHeterojunctionLewis acids and basesMaterials scienceBase (topology)Inorganic chemistryChemistryNanotechnologyChemical engineeringCatalysisElectrodeElectrochemistryPhysical chemistryOptoelectronicsMathematical analysisBiochemistryQuantum mechanicsMathematicsEngineeringPhysicsAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsAdvanced battery technologies research