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      Coordination effect of network NiO nanosheet and a carbon layer on the cathode side in constructing a high-performance lithium–sulfur battery

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          Abstract

          Network structured NiO sheets served as a mediator for lithium-sulfur battery coupled with a carbon layer on the cathode side in combination prevented the dissolution of polysulfides, enhanced the rate capability and long-term stability.

          Abstract

          Effectively preventing polysulfides from dissolving during the discharge/charge process to improve the performance of a lithium–sulfur battery is one of the essential requirements for commercialization. An NiO sheet with a network structure was developed via a simple two-step method and used as a mediator for a lithium–sulfur battery coupled with a carbon layer on the cathode side. Specifically, by introducing a thin carbon layer on the cathode side of the separator the dissolution of polysulfides was effectively hindered, and moreover the rate capability and long-term stability were effectively enhanced by the further addition of network NiO nanosheets owing to their mesoporous channels and the NiO–S interaction. Besides, in comparison with the cell performance at different S loadings, the cathode with 80 wt% of S in the total electrode exhibited a high specific capacity and excellent rate performance up to 5C. In addition, although the redox potential range of NiO did not form part of the recharging potential window, NiO exhibited an obvious interaction with polysulfides and limited their tendency to dissolve. The present study demonstrates that the joint action of network NiO and the carbon layer presents great potential to be used in low-cost and high-energy lithium–sulfur batteries and provides important guidance for the design of a multifunctional sulfur host for the battery cathodes.

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          Most cited references53

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          Towards greener and more sustainable batteries for electrical energy storage.

          Ever-growing energy needs and depleting fossil-fuel resources demand the pursuit of sustainable energy alternatives, including both renewable energy sources and sustainable storage technologies. It is therefore essential to incorporate material abundance, eco-efficient synthetic processes and life-cycle analysis into the design of new electrochemical storage systems. At present, a few existing technologies address these issues, but in each case, fundamental and technological hurdles remain to be overcome. Here we provide an overview of the current state of energy storage from a sustainability perspective. We introduce the notion of sustainability through discussion of the energy and environmental costs of state-of-the-art lithium-ion batteries, considering elemental abundance, toxicity, synthetic methods and scalability. With the same themes in mind, we also highlight current and future electrochemical storage systems beyond lithium-ion batteries. The complexity and importance of recycling battery materials is also discussed.
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            A highly ordered nanostructured carbon-sulphur cathode for lithium-sulphur batteries.

            The Li-S battery has been under intense scrutiny for over two decades, as it offers the possibility of high gravimetric capacities and theoretical energy densities ranging up to a factor of five beyond conventional Li-ion systems. Herein, we report the feasibility to approach such capacities by creating highly ordered interwoven composites. The conductive mesoporous carbon framework precisely constrains sulphur nanofiller growth within its channels and generates essential electrical contact to the insulating sulphur. The structure provides access to Li+ ingress/egress for reactivity with the sulphur, and we speculate that the kinetic inhibition to diffusion within the framework and the sorption properties of the carbon aid in trapping the polysulphides formed during redox. Polymer modification of the carbon surface further provides a chemical gradient that retards diffusion of these large anions out of the electrode, thus facilitating more complete reaction. Reversible capacities up to 1,320 mA h g(-1) are attained. The assembly process is simple and broadly applicable, conceptually providing new opportunities for materials scientists for tailored design that can be extended to many different electrode materials.
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              A highly efficient polysulfide mediator for lithium-sulfur batteries.

              The lithium-sulfur battery is receiving intense interest because its theoretical energy density exceeds that of lithium-ion batteries at much lower cost, but practical applications are still hindered by capacity decay caused by the polysulfide shuttle. Here we report a strategy to entrap polysulfides in the cathode that relies on a chemical process, whereby a host--manganese dioxide nanosheets serve as the prototype--reacts with initially formed lithium polysulfides to form surface-bound intermediates. These function as a redox shuttle to catenate and bind 'higher' polysulfides, and convert them on reduction to insoluble lithium sulfide via disproportionation. The sulfur/manganese dioxide nanosheet composite with 75 wt% sulfur exhibits a reversible capacity of 1,300 mA h g(-1) at moderate rates and a fade rate over 2,000 cycles of 0.036%/cycle, among the best reported to date. We furthermore show that this mechanism extends to graphene oxide and suggest it can be employed more widely.
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                Author and article information

                Contributors
                Journal
                JMCAET
                Journal of Materials Chemistry A
                J. Mater. Chem. A
                Royal Society of Chemistry (RSC)
                2050-7488
                2050-7496
                2018
                2018
                : 6
                : 15
                : 6503-6509
                Affiliations
                [1 ]Key Laboratory of Material Chemistry for Energy Conversion and Storage (Huazhong University of Science and Technology)
                [2 ]Ministry of Education
                [3 ]Hubei Key Laboratory of Material Chemistry and Service Failure
                [4 ]School of Chemistry and Chemical Engineering
                [5 ]Huazhong University of Science and Technology
                [6 ]State Key Laboratory Base of Eco-chemical Engineering
                [7 ]College of Chemistry and Molecular Engineering
                [8 ]Qingdao University of Science & Technology
                [9 ]Qingdao 266042
                [10 ]P. R. China
                [11 ]Department of Applied Physics
                [12 ]The Hong Kong Polytechnic University
                [13 ]Kowloon
                [14 ]Hong Kong
                Article
                10.1039/C8TA00270C
                0eb2cff9-1816-4f87-8994-b46e65b63f8c
                © 2018

                http://rsc.li/journals-terms-of-use

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