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    Use of microbial carbonation process to enable self‑carbonation of reactive MgO cement mixes

    New search for: Hoang, Tung
    New search for: Dung, Nguyen Tien
    New search for: Unluer, Cise
    New search for: Chu, Jian

    Abstract The low hydration and carbonation of reactive MgO cement (RMC) under ambient conditions causes prolonged setting and low compressive strengths (~4 MPa). This study proposed a unique technique which led to the enhancement of the hydration and carbonation processes via the synergistic combination of microbial carbonation process (MCP) with a hydration agent (HA) that enabled the self‑carbonation of RMC-based mixes without using of any special curing environments. Through hydrolysing urea (CO(NH2)2) using ureolytic bacteria, CO3 2− ions were produced to facilitate the carbonation of dissolved Mg2+ ions to form hydrated magnesium hydroxy carbonates (HMHCs). The self‑carbonation of RMC enabled by the MCP resulted in formation of brucite with a poor crystallinity and its rapid conversion into HMHCs, which improved the setting time and compressive strength of RMC-based samples. The simultaneous use of MCP with 2 M urea and HA revealed HMHCs with improved morphologies, resulting in the highest compressive strength (~15 MPa).

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    Use of microbial carbonation process to enable self‑carbonation of reactive MgO cement mixes

    New search for: Hoang, Tung
    New search for: Dung, Nguyen Tien
    New search for: Unluer, Cise
    New search for: Chu, Jian

    Abstract The low hydration and carbonation of reactive MgO cement (RMC) under ambient conditions causes prolonged setting and low compressive strengths (~4 MPa). This study proposed a unique technique which led to the enhancement of the hydration and carbonation processes via the synergistic combination of microbial carbonation process (MCP) with a hydration agent (HA) that enabled the self‑carbonation of RMC-based mixes without using of any special curing environments. Through hydrolysing urea (CO(NH2)2) using ureolytic bacteria, CO3 2− ions were produced to facilitate the carbonation of dissolved Mg2+ ions to form hydrated magnesium hydroxy carbonates (HMHCs). The self‑carbonation of RMC enabled by the MCP resulted in formation of brucite with a poor crystallinity and its rapid conversion into HMHCs, which improved the setting time and compressive strength of RMC-based samples. The simultaneous use of MCP with 2 M urea and HA revealed HMHCs with improved morphologies, resulting in the highest compressive strength (~15 MPa).

    Access

    Check access
    Check availability in my library
    Order at Subito €

    Use of microbial carbonation process to enable self‑carbonation of reactive MgO cement mixes

    New search for: Hoang, Tung
    New search for: Dung, Nguyen Tien
    New search for: Unluer, Cise
    New search for: Chu, Jian

    Abstract The low hydration and carbonation of reactive MgO cement (RMC) under ambient conditions causes prolonged setting and low compressive strengths (~4 MPa). This study proposed a unique technique which led to the enhancement of the hydration and carbonation processes via the synergistic combination of microbial carbonation process (MCP) with a hydration agent (HA) that enabled the self‑carbonation of RMC-based mixes without using of any special curing environments. Through hydrolysing urea (CO(NH2)2) using ureolytic bacteria, CO3 2− ions were produced to facilitate the carbonation of dissolved Mg2+ ions to form hydrated magnesium hydroxy carbonates (HMHCs). The self‑carbonation of RMC enabled by the MCP resulted in formation of brucite with a poor crystallinity and its rapid conversion into HMHCs, which improved the setting time and compressive strength of RMC-based samples. The simultaneous use of MCP with 2 M urea and HA revealed HMHCs with improved morphologies, resulting in the highest compressive strength (~15 MPa).

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    Title:

    Use of microbial carbonation process to enable self‑carbonation of reactive MgO cement mixes

    Contributors:

    Hoang, Tung (author) / Dung, Nguyen Tien (author) / Unluer, Cise (author) / Chu, Jian (author)

    Published in:

    Cement and Concrete Research ; 143

    Publication date:

    2021-02-04

    ISSN:

    0008-8846

    DOI:

    https://doi.org/10.1016/j.cemconres.2021.106391

    Type of media:

    Article (Journal)

    Type of material:

    Electronic Resource

    Language:

    English

    Keywords:

    MgO (D) , Hydration (A) , Carbonation (C) , Acceleration (A) , Compressive strength (C)

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