Litcius/Paper detail

Antimonene Allotropes α- and β-Phases as Promising Anchoring Materials for Lithium–Sulfur Batteries

Deobrat Singh, Sanjeev K. Gupta, Tanveer Hussain, Yogesh Sonvane, P. N. Gajjar, Rajeev Ahuja

2021Energy & Fuels24 citationsDOIOpen Access PDF

Abstract

In a quest to mitigate the undesirable shuttling effect that hampers the performance of Li-S batteries, we adopted first-principles calculations to study the anchoring mechanism of lithium polysulfides on antimonene phases, i.e., alpha-Sb and beta-Sb. The anchoring mechanisms of LiPSs on alpha-Sb and beta-Sb were studied through calculations of binding energy, charge transfer, and vertical binding distances from the monolayer to LiPSs. The results indicated that pristine alpha-Sb and beta-Sb showed significant physisorption/chemisorption interactions toward LiPSs due to the considerable E-b, values (0.71-1.68 and 0.96-2.07 eV, respectively). Meanwhile, with single Sb vacancy, the binding strength was enhanced (0.83-2.91 eV) for the beta-Sb monolayer. Furthermore, we substituted the Sb atom with the Sn/Te atom and found stronger E-b (1.32 5.69 and 0.45-4.81 eV). All these bindings of LiPSs were much stronger than their interactions with those of electrolytes (DME/DOL) (E-b values: 0.20-1.16 and 0.17-1.07 eV). Also, we investigated the redistribution of electrons and the influence of electronic states near the Fermi level in DOS for LiPSs on alpha-Sb and beta-Sb. Our findings suggest that pristine and defected beta-Sb monolayers could be an excellent anchoring material for Li-S batteries.

Topics & Concepts

MonolayerMaterials scienceVacancy defectAnchoringChemisorptionLithium (medication)Chemical physicsAtom (system on chip)Fermi levelPhysisorptionBinding energyRedistribution (election)ElectronAdsorptionNanotechnologyChemistryCrystallographyPhysical chemistryAtomic physicsEndocrinologyComputer scienceQuantum mechanicsPolitical scienceEmbedded systemEngineeringPoliticsStructural engineeringPhysicsMedicineLawAdvanced Battery Materials and TechnologiesAdvancements in Battery MaterialsMXene and MAX Phase Materials