Abstract
Sulfur is considered to be one of the most promising cathode materials due to its high theoretical specific capacity and low cost. However, the insulating nature of sulfur and notorious “shuttle effect” of lithium polysulfides (LiPSs) lead to severe loss of active sulfur, poor redox kinetics, and rapid capacity fade. Herein, a hierarchical electrode design is proposed to address these issues synchronously, which integrates multiple building blocks with specialized functions into an ensemble to construct a self‐supported versatile cathode for lithium–sulfur batteries. Nickel foam acts as a robust conductive scaffold. The heteroatom‐doped host carbon with desired lithiophilicity and electronic conductivity serving as a reservoir for loading sulfur can trap LiPSs and promote electron transfer to interfacial adsorbed LiPSs and Ni3S2 sites. The sulfurized carbon nanofiber forest can facilitate the Li‐ion and electron transport and retard the LiPSs diffusion as a barrier layer. Sulfiphilic Ni3S2 acts as both a chemical anchor with strong adsorption affinity to LiPSs and an efficient electrocatalyst for accelerating kinetics for redox conversion reactions. Synergistically, all functional units promote the lithium ion coupled electron transfer for binding and redox conversion of LiPSs, resulting in high reversible capacities, remarkable cycle stability, and excellent rate capability.
Highlights
Sulfur is considered to be one of the most promising cathode materials due devoted to exploring reliable energy storage systems with high energy densito its high theoretical specific capacity and low cost
The dominant peaks in the X-ray diffraction (XRD) pattern of cleaned S/carbon nanofibers (CNFs)-host carbon (HC)-Ni3S2 correspond to metallic nickel resulting from Ni foam framework (Figure S6a, Supporting Information), and the XRD patterns of other components are compared in Figure S6b of the Supporting Information
The energy dispersive X-ray (EDX) elemental mapping of the ligament surface of S/carbon nanofibers and host carbon layers (CNF-HC)-Ni3S2 demonstrates that Ni and S elements are homogeneously dispersed in the carbon matrix without notable segregation (Figure S8, Supporting Information)
Summary
Programmed Design of a Lithium–Sulfur Battery Cathode by Integrating Functional Units. To satisfy the ever-increasing demands for the portable elec- tivity of S and Li2S/Li2S2 and the high solubility and diffusion tronic devices, electric vehicles, and renewable energy har- of LiPSs lead to high charge transfer resistance and sluggish vesting at a large scale, intensive research efforts have been kinetics of polysulfide redox reactions on the cathode. These issues likely result in low utilization of sulfur, loss.
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