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    COMPOSITE SOLID-STATE ELECTROLYTES, DEVICES WITH COMPOSITE SOLID-STATE ELECTROLYTES, AND METHODS FOR FABRICATION THEREOF

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    New search for: PING WEIWEI
    New search for: DONG QI
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    Precursors can be provided on a surface of a porous support layer and subjected to a temperature≤1200 K for a time≤60 seconds, so as to sinter the precursors into a porous scaffold. The porous scaffold can comprise an ion-conducting oxide. Filler materials can be provided on a surface of the porous scaffold. The filler materials can have a melting point in a range of 500-1100 K. The porous scaffold with filler materials can be subjected to a temperature≤1200 K for a time≤50 seconds, so as to melt the filler materials to form a non-porous composite solid-state electrolyte layer, with the filler materials infiltrating the porous scaffold. The solid-state electrolyte layer can be incorporated into a solid-state electrochemical energy device, such as a battery or fuel cell.

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    COMPOSITE SOLID-STATE ELECTROLYTES, DEVICES WITH COMPOSITE SOLID-STATE ELECTROLYTES, AND METHODS FOR FABRICATION THEREOF

    New search for: HU LIANGBING
    New search for: PING WEIWEI
    New search for: DONG QI
    New search for: HONG MIN

    Precursors can be provided on a surface of a porous support layer and subjected to a temperature≤1200 K for a time≤60 seconds, so as to sinter the precursors into a porous scaffold. The porous scaffold can comprise an ion-conducting oxide. Filler materials can be provided on a surface of the porous scaffold. The filler materials can have a melting point in a range of 500-1100 K. The porous scaffold with filler materials can be subjected to a temperature≤1200 K for a time≤50 seconds, so as to melt the filler materials to form a non-porous composite solid-state electrolyte layer, with the filler materials infiltrating the porous scaffold. The solid-state electrolyte layer can be incorporated into a solid-state electrochemical energy device, such as a battery or fuel cell.

    Access

    Download

    COMPOSITE SOLID-STATE ELECTROLYTES, DEVICES WITH COMPOSITE SOLID-STATE ELECTROLYTES, AND METHODS FOR FABRICATION THEREOF

    New search for: HU LIANGBING
    New search for: PING WEIWEI
    New search for: DONG QI
    New search for: HONG MIN

    Precursors can be provided on a surface of a porous support layer and subjected to a temperature≤1200 K for a time≤60 seconds, so as to sinter the precursors into a porous scaffold. The porous scaffold can comprise an ion-conducting oxide. Filler materials can be provided on a surface of the porous scaffold. The filler materials can have a melting point in a range of 500-1100 K. The porous scaffold with filler materials can be subjected to a temperature≤1200 K for a time≤50 seconds, so as to melt the filler materials to form a non-porous composite solid-state electrolyte layer, with the filler materials infiltrating the porous scaffold. The solid-state electrolyte layer can be incorporated into a solid-state electrochemical energy device, such as a battery or fuel cell.

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    Title:

    COMPOSITE SOLID-STATE ELECTROLYTES, DEVICES WITH COMPOSITE SOLID-STATE ELECTROLYTES, AND METHODS FOR FABRICATION THEREOF

    Additional title:

    ZUSAMMENGESETZTE FESTKÖRPERELEKTROLYTEN, VORRICHTUNGEN MIT ZUSAMMENGESETZTEN FESTKÖRPERELEKTROLYTEN UND VERFAHREN ZU IHRER HERSTELLUNG
    ÉLECTROLYTES COMPOSITES SOLIDES, DISPOSITIFS À ÉLECTROLYTES COMPOSITES SOLIDES, ET LEURS PROCÉDÉS DE FABRICATION

    Contributors:

    HU LIANGBING (author) / PING WEIWEI (author) / DONG QI (author) / HONG MIN (author)

    Publication date:

    2024-10-30

    Type of media:

    Patent

    Type of material:

    Electronic Resource

    Language:

    English

    Classification:

    IPC:  H01M Verfahren oder Mittel, z.B. Batterien, für die direkte Umwandlung von chemischer in elektrische Energie , PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY / C04B Kalk , LIME

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