Single-Atom Catalysts with Unsaturated Co–N₂ Active Sites Based on a C₂N 2D-Organic Framework for Efficient Sulfur Redox Reaction

Abstract: The lithium−sulfur battery (LSB) is a viable option for the next generation of energy storage systems. However, the shuttle effect of lithium polysulfides (LiPS) and the poor electrical conductivity of sulfur and lithium sulfides limit its deployment. Here, we report on a 2D-organic framework, C 2 N, with a high loading of low-coordination cobalt single atoms (Co-SAs/C 2 N) as an effective sulfur host in LSB cathodes. Experimental and computational results reveal that unsaturated Co−N 2 active sites with an as… Show more

“…22–24 The noble metal, Pt as one catalytic candidate, has been incorporated into graphene for promoting the redox cycle of soluble LiPSs, and other non-noble metals such as V can efficiently capture dissolved LiPSs and catalyze the conversion of LiPSs to Li 2 S during the cycling process as well. 25,26 Likewise, MoS 2 , 27,28 nitrogen-doped graphene, 29–31 and other materials 32 also possess moderate chemical interactions and show fast conversion to LiPSs through 3d-TM doping. In fact, the adsorption of LiPSs and even electrochemical processes can benefit from appropriately designed 3d-TM active sites with strong TM–S bonds.…”

Theoretical probing of monolayer BiI₃ as an electrolyte separator and 3d-TM-doped BiI₃ as electrocatalysts toward high-performance lithium–sulfur batteries

“…22–24 The noble metal, Pt as one catalytic candidate, has been incorporated into graphene for promoting the redox cycle of soluble LiPSs, and other non-noble metals such as V can efficiently capture dissolved LiPSs and catalyze the conversion of LiPSs to Li 2 S during the cycling process as well. 25,26 Likewise, MoS 2 , 27,28 nitrogen-doped graphene, 29–31 and other materials 32 also possess moderate chemical interactions and show fast conversion to LiPSs through 3d-TM doping. In fact, the adsorption of LiPSs and even electrochemical processes can benefit from appropriately designed 3d-TM active sites with strong TM–S bonds.…”

Theoretical probing of monolayer BiI₃ as an electrolyte separator and 3d-TM-doped BiI₃ as electrocatalysts toward high-performance lithium–sulfur batteries

Unlocking Performance: The Transformative Influence of Single Atom Catalysts on Advanced Lithium‐Sulfur Battery Design

Coordinating lithium polysulfides to inhibit intrinsic clustering behavior and facilitate sulfur redox conversion in lithium-sulfur batteries