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W3131192614 endingPage "129094" @default.
W3131192614 startingPage "129094" @default.
W3131192614 abstract "Huge volume expansion and inferior electrical conductivity are the two main obstacles to limit the practical applications of high-capacity molybdenum disulfide (MoS2) materials, which has been recognized as ideal anode materials for rechargeable lithium-ion batteries. Herein, an interfacial reinforcement structure design is proposed by conformally growing few-layered MoS2 nanosheets on carbon coated ultralong TiO2 nanotubes (TiO2@[email protected]2) to stabilize the solid electrolyte interface (SEI) of MoS2-based electrode. The interlayer carbon coating on TiO2 nanotubes effectively improves the interfacial contact between MoS2 nanosheets and TiO2 nanotubes by forming Ti-O-C and C-S chemical bonds between TiO2/carbon coating and MoS2/carbon coating, respectively, avoiding MoS2 nanosheets detaching from TiO2 nanotubes. Meanwhile, the carbon coating serves as a buffering cushion to alleviate mechanical strain at the interface of MoS2 nanosheets and TiO2 nanotubes. Besides, it enhances the adsorption performance of Li ions on the surface of MoS2 and at the interface sites between MoS2 and TiO2. While three-dimensional rigid TiO2 nanotubes networks work as mechanical support to suppress reaggregating and restacking of MoS2 nanosheets, and provide fast transportation expressways for electrons/ions. Thus, the TiO2@[email protected]2 electrode exhibits ultrafast charge/discharge capability, a high reversible capacity of 1150 mAh g−1 at 0.1 A g−1, and superior cycling performance with 90% capacity retention after 1500 cycles at 1.0 A g−1. This interfacial reinforcement structure design provides valuable experience to benefit rational design of alloy/conversion-typed materials electrode with high-performance." @default.
W3131192614 created "2021-03-01" @default.
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W3131192614 date "2021-07-01" @default.
W3131192614 modified "2023-10-13" @default.
W3131192614 title "Interfacial reinforcement structure design towards ultrastable lithium storage in MoS2-based composited electrode" @default.
W3131192614 cites W1901595504 @default.
W3131192614 cites W2013209195 @default.
W3131192614 cites W2021172010 @default.
W3131192614 cites W2021435259 @default.
W3131192614 cites W2042186775 @default.
W3131192614 cites W2050475460 @default.
W3131192614 cites W2070284228 @default.
W3131192614 cites W2086641534 @default.
W3131192614 cites W2091875228 @default.
W3131192614 cites W2119192493 @default.
W3131192614 cites W2151207643 @default.
W3131192614 cites W2260791627 @default.
W3131192614 cites W2286534601 @default.
W3131192614 cites W2401287280 @default.
W3131192614 cites W2412840658 @default.
W3131192614 cites W2413646910 @default.
W3131192614 cites W2513003834 @default.
W3131192614 cites W2516437648 @default.
W3131192614 cites W2517352822 @default.
W3131192614 cites W2520090679 @default.
W3131192614 cites W2554121502 @default.
W3131192614 cites W2557875418 @default.
W3131192614 cites W2560701263 @default.
W3131192614 cites W2575729113 @default.
W3131192614 cites W2577981653 @default.
W3131192614 cites W2581019057 @default.
W3131192614 cites W2593815020 @default.
W3131192614 cites W2599018039 @default.
W3131192614 cites W2604380954 @default.
W3131192614 cites W2605361618 @default.
W3131192614 cites W2606812455 @default.
W3131192614 cites W2756288503 @default.
W3131192614 cites W2761617117 @default.
W3131192614 cites W2768865870 @default.
W3131192614 cites W2769298478 @default.
W3131192614 cites W2789664389 @default.
W3131192614 cites W2790905261 @default.
W3131192614 cites W2809003160 @default.
W3131192614 cites W2882971906 @default.
W3131192614 cites W2888564300 @default.
W3131192614 cites W2888776702 @default.
W3131192614 cites W2897729659 @default.
W3131192614 cites W2901261596 @default.
W3131192614 cites W2904955515 @default.
W3131192614 cites W2918349372 @default.
W3131192614 cites W2919027421 @default.
W3131192614 cites W2921335110 @default.
W3131192614 cites W2921964354 @default.
W3131192614 cites W2923900205 @default.
W3131192614 cites W2941187502 @default.
W3131192614 cites W2945365173 @default.
W3131192614 cites W2946785493 @default.
W3131192614 cites W2955854763 @default.
W3131192614 cites W2962779637 @default.
W3131192614 cites W2968627901 @default.
W3131192614 cites W2970625255 @default.
W3131192614 cites W2978313837 @default.
W3131192614 cites W2991414878 @default.
W3131192614 cites W3000364848 @default.
W3131192614 cites W3000719013 @default.
W3131192614 cites W3001254049 @default.
W3131192614 cites W3003863834 @default.
W3131192614 cites W3005779694 @default.
W3131192614 cites W3006304185 @default.
W3131192614 cites W3006820385 @default.
W3131192614 cites W3009966763 @default.
W3131192614 cites W3021624385 @default.
W3131192614 cites W3027029412 @default.
W3131192614 cites W3027088657 @default.
W3131192614 cites W3034175095 @default.
W3131192614 cites W3043138955 @default.
W3131192614 cites W3120018130 @default.
W3131192614 cites W3125828782 @default.
W3131192614 cites W3134932327 @default.
W3131192614 cites W323108720 @default.
W3131192614 doi "https://doi.org/10.1016/j.cej.2021.129094" @default.
W3131192614 hasPublicationYear "2021" @default.
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