2018
DOI: 10.1002/aenm.201802768
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Conductive and Catalytic Triple‐Phase Interfaces Enabling Uniform Nucleation in High‐Rate Lithium–Sulfur Batteries

Abstract: Rechargeable lithium–sulfur batteries have attracted tremendous scientific attention owing to their superior energy density. However, the sulfur electrochemistry involves multielectron redox reactions and complicated phase transformations, while the final morphology of solid‐phase Li2S precipitates largely dominate the battery's performance. Herein, a triple‐phase interface among electrolyte/CoSe2/G is proposed to afford strong chemisorption, high electrical conductivity, and superb electrocatalysis of polysul… Show more

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Cited by 570 publications
(340 citation statements)
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“…[95][96][97][98] Moreover, SACs achieve main strategies in electrocatalyst design: increasing the active sites and enhancing the intrinsic activity. [95][96][97][98] Moreover, SACs achieve main strategies in electrocatalyst design: increasing the active sites and enhancing the intrinsic activity.…”
Section: Single Atom Catalysts (Sacs)mentioning
confidence: 99%
“…[95][96][97][98] Moreover, SACs achieve main strategies in electrocatalyst design: increasing the active sites and enhancing the intrinsic activity. [95][96][97][98] Moreover, SACs achieve main strategies in electrocatalyst design: increasing the active sites and enhancing the intrinsic activity.…”
Section: Single Atom Catalysts (Sacs)mentioning
confidence: 99%
“…[32,34] Carbides like TiC were embedded in the mesopores of CMK-3 in the presence of supercritical fluid. [37] CoSe 2 was reported to modify the separator and form a triple-phase electrolyte/CoSe 2 /graphene interface, favorably enhancing the kinetic behaviors of lithium polysulfides and regulating the uniform nucleation of Li 2 S. [38] Considering the exciting investigation, we chose the MoSe 2 as the polar material to further examine the applicability and workability of metal selenides to LSBs. [37] CoSe 2 was reported to modify the separator and form a triple-phase electrolyte/CoSe 2 /graphene interface, favorably enhancing the kinetic behaviors of lithium polysulfides and regulating the uniform nucleation of Li 2 S. [38] Considering the exciting investigation, we chose the MoSe 2 as the polar material to further examine the applicability and workability of metal selenides to LSBs.…”
Section: Sulfiphilic Few-layered Mose 2 Nanoflakes Decorated Rgo As Amentioning
confidence: 99%
“…Encapsulation of sulfur in conductive matrix is a straightforward approach to maximize the redox reaction interfaces for sulfur conversion . This strategy is recently coupled with precise surface modification, endowing electrode substrates or functional separators with lithiophilicity and sulfiphilicity to kinetically promote S/Li 2 S precipitation and regulate LiPS transport . Directly blending metal oxides, sulfides, nitrides, and carbide with various carbonaceous hosts has demonstrated considerable merits to mediate sulfur species’ behaviors through chemisorption and/or electrocatalysis mechanisms .…”
Section: Introductionmentioning
confidence: 99%