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    The Anode Challenge for Lithium‐Ion Batteries: A Mechanochemically Synthesized Sn–Fe–C Composite Anode Surpasses Graphitic Carbon

    Neue Suche nach: Dong, Zhixin
    Neue Suche nach: Zhang, Ruibo
    Neue Suche nach: Ji, Dongsheng
    Neue Suche nach: Chernova, Natasha A.
    Neue Suche nach: Karki, Khim
    Neue Suche nach: Sallis, Shawn
    Neue Suche nach: Piper, Louis
    Neue Suche nach: Whittingham, M. Stanley

    Carbon‐based anodes are the key limiting factor in increasing the volumetric capacity of lithium‐ion batteries. Tin‐based composites are one alternative approach. Nanosized Sn–Fe–C anode materials are mechanochemically synthesized by reducing SnO with Ti in the presence of carbon. The optimum synthesis conditions are found to be 1:0.25:10 for initial ratio of SnO, Ti, and graphite with a total grinding time of 8 h. This optimized composite shows excellent extended cycling at the C/10 rate, delivering a first charge capacity as high as 740 mAh g−1 and 60% of which still remained after 170 cycles. The calculated volumetric capacity significantly exceeds that of carbon. It also exhibits excellent rate capability, delivering volumetric capacity higher than 1.6 Ah cc−1 over 140 cycles at the 1 C rate.

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    The Anode Challenge for Lithium‐Ion Batteries: A Mechanochemically Synthesized Sn–Fe–C Composite Anode Surpasses Graphitic Carbon

    Neue Suche nach: Dong, Zhixin
    Neue Suche nach: Zhang, Ruibo
    Neue Suche nach: Ji, Dongsheng
    Neue Suche nach: Chernova, Natasha A.
    Neue Suche nach: Karki, Khim
    Neue Suche nach: Sallis, Shawn
    Neue Suche nach: Piper, Louis
    Neue Suche nach: Whittingham, M. Stanley

    Carbon‐based anodes are the key limiting factor in increasing the volumetric capacity of lithium‐ion batteries. Tin‐based composites are one alternative approach. Nanosized Sn–Fe–C anode materials are mechanochemically synthesized by reducing SnO with Ti in the presence of carbon. The optimum synthesis conditions are found to be 1:0.25:10 for initial ratio of SnO, Ti, and graphite with a total grinding time of 8 h. This optimized composite shows excellent extended cycling at the C/10 rate, delivering a first charge capacity as high as 740 mAh g−1 and 60% of which still remained after 170 cycles. The calculated volumetric capacity significantly exceeds that of carbon. It also exhibits excellent rate capability, delivering volumetric capacity higher than 1.6 Ah cc−1 over 140 cycles at the 1 C rate.

    Zugriff

    Download

    The Anode Challenge for Lithium‐Ion Batteries: A Mechanochemically Synthesized Sn–Fe–C Composite Anode Surpasses Graphitic Carbon

    Neue Suche nach: Dong, Zhixin
    Neue Suche nach: Zhang, Ruibo
    Neue Suche nach: Ji, Dongsheng
    Neue Suche nach: Chernova, Natasha A.
    Neue Suche nach: Karki, Khim
    Neue Suche nach: Sallis, Shawn
    Neue Suche nach: Piper, Louis
    Neue Suche nach: Whittingham, M. Stanley

    Carbon‐based anodes are the key limiting factor in increasing the volumetric capacity of lithium‐ion batteries. Tin‐based composites are one alternative approach. Nanosized Sn–Fe–C anode materials are mechanochemically synthesized by reducing SnO with Ti in the presence of carbon. The optimum synthesis conditions are found to be 1:0.25:10 for initial ratio of SnO, Ti, and graphite with a total grinding time of 8 h. This optimized composite shows excellent extended cycling at the C/10 rate, delivering a first charge capacity as high as 740 mAh g−1 and 60% of which still remained after 170 cycles. The calculated volumetric capacity significantly exceeds that of carbon. It also exhibits excellent rate capability, delivering volumetric capacity higher than 1.6 Ah cc−1 over 140 cycles at the 1 C rate.

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    Titel:

    The Anode Challenge for Lithium‐Ion Batteries: A Mechanochemically Synthesized Sn–Fe–C Composite Anode Surpasses Graphitic Carbon

    Beteiligte:

    Dong, Zhixin (Autor:in) / Zhang, Ruibo (Autor:in) / Ji, Dongsheng (Autor:in) / Chernova, Natasha A. (Autor:in) / Karki, Khim (Autor:in) / Sallis, Shawn (Autor:in) / Piper, Louis (Autor:in) / Whittingham, M. Stanley (Autor:in)

    Erschienen in:

    Advanced Science ; 3

    Erscheinungsdatum:

    01.04.2016

    Format / Umfang:

    8 pages

    ISSN:

    2198-3844

    DOI:

    https://doi.org/10.1002/advs.201500229

    Medientyp:

    Aufsatz (Zeitschrift)

    Format:

    Elektronische Ressource

    Sprache:

    Englisch

    Schlagwörter:

    volumetric capacity , anode , high energy ball mill , lithium‐ion battery , Sn2Fe

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