Litcius/Paper detail

Multifunctional SnO2 QDs/MXene Heterostructures as Laminar Interlayers for Improved Polysulfide Conversion and Lithium Plating Behavior

Shungui Deng, Weiwei Sun, Jiawei Tang, Mohammad Jafarpour, Frank Nüesch, Jakob Heier, Chuanfang Zhang

2024Nano-Micro Letters55 citationsDOIOpen Access PDF

Abstract

Abstract Poor cycling stability in lithium–sulfur (Li–S) batteries necessitates advanced electrode/electrolyte design and innovative interlayer architectures. Heterogeneous catalysis has emerged as a promising approach, leveraging the adsorption and catalytic performance on lithium polysulfides (LiPSs) to inhibit LiPSs shuttling and improve redox kinetics. In this study, we report an ultrathin and laminar SnO 2 @MXene heterostructure interlayer (SnO 2 @MX), where SnO 2 quantum dots (QDs) are uniformly distributed across the MXene layer. The combined structure of SnO 2 QDs and MXene, along with the creation of numerous active boundary sites with coordination electron environments, plays a critical role in manipulating the catalytic kinetics of sulfur species. The Li–S cell with the SnO 2 @MX-modified separator not only demonstrates superior electrochemical performance compared to cells with a bare separator but also induces homogeneous Li deposition during cycling. As a result, an areal capacity of 7.6 mAh cm −2 under a sulfur loading of 7.5 mg cm −2 and a high stability over 500 cycles are achieved. Our work demonstrates a feasible strategy of utilizing a laminar separator interlayer for advanced Li–S batteries awaiting commercialization and may shed light on the understanding of heterostructure catalysis with enhanced reaction kinetics.

Topics & Concepts

PolysulfideMaterials scienceSeparator (oil production)HeterojunctionChemical engineeringElectrolyteCatalysisNanotechnologyElectrochemistryKineticsElectrodeQuantum dotChemistryOptoelectronicsBiochemistryQuantum mechanicsPhysical chemistryPhysicsThermodynamicsEngineeringAdvanced Battery Materials and TechnologiesMXene and MAX Phase MaterialsAdvancements in Battery Materials