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      Phase formation in alloy-type anode materials in the quaternary system Li–Sn–Si–C

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          Abstract

          Investigations on the thermodynamics of alloy-type anode materials have been carried out for the quaternary Li–C–Si–Sn system. Phase equilibria and phase stabilities were characterized in the binary subsystems Li–C, Li–Si, Li–Sn. The Calphad method was first used to optimize or completely re-establish all binary subsystems containing Li. For reasons of consistency, the binary subsystem Si–C had to be revisited and its Calphad description was modified. The ternary phase diagrams were then tentatively calculated by extrapolation from the binary subsystems and confirmed by key experiments. No ternary compounds were found. In order to verify the applicability of the anode materials in real batteries, some of the materials were nanostructured by ball milling and spark plasma sintering, the corresponding nanostructures were characterized. Theoretical predictions that nanograined Li 2C 2 can also be used as cathode material were verified experimentally. The methodologies worked out in the present project (e. g. nanoscale structure transmission electron microscopy analysis, glow discharge optical emission spectroscopy) were also employed in other projects and led to publications concerning other materials such as Mg alloys, carbon nanofibers and an Mn-based antiperovskite.

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          Phase formation in alloy-type anode materials in the quaternary system Li–Sn–Si–C

          Investigations on the thermodynamics of alloy-type anode materials have been carried out for the quaternary Li–C–Si–Sn system. Phase equilibria and phase stabilities were characterized in the binary subsystems Li–C, Li–Si, Li–Sn. The Calphad method was first used to optimize or completely re-establish all binary subsystems containing Li. For reasons of consistency, the binary subsystem Si–C had to be revisited and its Calphad description was modified. The ternary phase diagrams were then tentatively calculated by extrapolation from the binary subsystems and confirmed by key experiments. No ternary compounds were found. In order to verify the applicability of the anode materials in real batteries, some of the materials were nanostructured by ball milling and spark plasma sintering, the corresponding nanostructures were characterized. Theoretical predictions that nanograined Li 2 C 2 can also be used as cathode material were verified experimentally. The methodologies worked out in the present project (e. g. nanoscale structure transmission electron microscopy analysis, glow discharge optical emission spectroscopy) were also employed in other projects and led to publications concerning other materials such as Mg alloys, carbon nanofibers and an Mn-based antiperovskite.
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            Author and article information

            Journal
            ijmr
            International Journal of Materials Research
            Carl Hanser Verlag
            1862-5282
            2195-8556
            10 November 2017
            : 108
            : 11
            : 933-941
            Affiliations
            a Friedrich Schiller University, Otto Schott Institute of Materials Research, Jena, Germany
            b Clausthal University of Technology, Institute of Metallurgy, Clausthal-Zellerfeld, Germany
            c Beijing University of Technology, College of Materials Science and Engineering, Key Laboratory of Advanced Functional Materials, Beijing, China
            d Friedrich Schiller University, Center for Energy and Environmental Chemistry, Jena, Germany
            Author notes
            [* ] Correspondence address, Dr. Song-Mao Liang, Institute of Metallurgy, Clausthal University of Technology, Robert-Koch-Str. 42, D-38678 Clausthal-Zellerfeld, Germany, Tel.: +49-(0)5323-72 2077, Fax: +49-(0)5323-72 3120, E-mail: songmao.liang@ 123456tu-clausthal.de songmao.liang@ 123456gmail.com , Web: http://www.imet.tu-clausthal.de/agrsf/
            Article
            MK111559
            10.3139/146.111559
            b25de93e-abbd-4815-8120-cdde2585cdf7
            © 2017, Carl Hanser Verlag, München
            History
            : 29 July 2017
            : 21 August 2017
            : 9 October 2017
            Page count
            References: 41, Pages: 9
            Categories
            Original Contributions

            Materials technology,Materials characterization,Materials science
            Phase formation,Li battery anodes,Thermodynamics,Li–C–Si–Sn system

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