Freestanding Fe0.4co8.6s8 Nanotube/Nanosheet Arrays On Carbon Cloth As A Host For High-Performance Li/Ses2 Batteries

To inhibit the shuttle effect and promote the electrochemical performance of the Li/SeS2 batteries, the three-dimensional (3D) conductive composite of freestanding Fe0.4C8.6S8 nanotube/nanosheet arrays on carbon cloth (CC@ Fe0.4C8.6S8) is designed and synthesized to host SeS2. The integrated host appears in the form of the Fe0.4C8.6S8 nanosheets growing on the surface of nanotubes supported by carbon cloth, which provides a great surface area and offers secondary protection from nanosheets against shuttle of polyselenides/sulfides on the basis of nanotubes. Such enhanced physical confinement, along with chemical immobilization of the polar Fe0.4C8.6S8, ensures high capability to adsorb polyselenides/sulfides. The well-constructed conductive network facilitates the fast redox reaction to lessen the dissolution and diffusion of polyselenides/sulfides. It was demonstrated by the adsorption test and explained by the systematic self-discharge experiments. As a result, upon the elevated current density and/or SeS2 loading, the deliberately designed architecture of CC@Fe0.4C8.6S8, can exhibit large reversible capacity as well as great energy density. Specifically, with the areal loading of 2 mg cm(-2), the CC@Fe0.4Co8.6S8/SeS2 electrode delivers high discharge capacity of 888 mAh g 1 at 1.0 A g(-1) and excellent rate capability (585 mAh g(-1) at 4.0 A g(-1)). In addition, with the areal loading increasing to 3.6 mg cm(2), the cathode still reaches an ultrahigh capacity of 703 mAh g(-1) at 1.0 A g(-1). Upon further increasing SeS2 loading to 4.8 mg cm(2), the corresponding areal energy density reaches 8.05 mWh cm(-2) at 0.2 A g(-1). This contribution adopts a less complex structure to address the issues in Li/SeS2 batteries. The effectiveness of shuttle inhibition is explained quantitatively through a systematic study on self-discharge phenomena, besides the electrochemical performance.