• Bulletin of the Chinese Ceramic Society
  • Vol. 42, Issue 11, 3978 (2023)
LAI Jin1, LUO Qi1, WANG Wenyao1, HUANG Wenhao1, LIU Fengyue1, ZHUANG Rongchuan2, and WANG Junfeng1
Author Affiliations
  • 1[in Chinese]
  • 2[in Chinese]
  • show less
    DOI: Cite this Article
    LAI Jin, LUO Qi, WANG Wenyao, HUANG Wenhao, LIU Fengyue, ZHUANG Rongchuan, WANG Junfeng. Preparation and Properties Characterization of Neutralization Slag Based Geopolymers[J]. Bulletin of the Chinese Ceramic Society, 2023, 42(11): 3978 Copy Citation Text show less
    References

    [3] DENG D QLIU LYAO Z Let al. A practice of ultra-fine tailings disposal as filling material in a gold mine[J]. Journal of Environmental Management2017196: 100-109.

    [6] WANG CLI Z FZHOU Z Het al. Compatibility of different fibres with red mud-based geopolymer grouts[J]. Construction and Building Materials2022315: 125742.

    [7] LUO QLIU Y TDONG B Qet al. Lithium slag-based geopolymer synthesized with hybrid solid activators[J]. Construction and Building Materials2023365: 130070.

    [8] KIRUBAJINY PSAYANTHAN RJAY S. Formulating eco-friendly geopolymer foam concrete by alkali-activation of ground brick waste[J]. Journal of Cleaner Production2021325: 129180.

    [9] LI Y LYIN JYUAN Qet al. Greener strain-hardening cementitious composites (SHCC) with a novel alkali-activated cement[J]. Cement and Concrete Composites2022134: 104735.

    [12] ZHANG B FYU TDENG L Let al. Ion-adsorption type rare earth tailings for preparation of alkali-based geopolymer with capacity for heavy metals immobilization[J]. Cement and Concrete Composites2022134: 104768.

    [14] WANG YZHONG HZHANG M Z. Experimental study on static and dynamic properties of fly ash-slag based strain hardening geopolymer composites[J]. Cement and Concrete Composites2022129: 104481.

    [16] LI M SLUO RQIN L Let al. High temperature properties of graphene oxide modified metakaolin based geopolymer paste[J]. Cement and Concrete Composites2022125: 104318.

    [17] WONGSA ABOONSERM KWAISURASINGHA Cet al. Use of municipal solid waste incinerator (MSWI) bottom ash in high calcium fly ash geopolymer matrix[J]. Journal of Cleaner Production2017148: 49-59.

    [18] WANG Y GLIU X MZHANG Wet al. Effects of Si/Al ratio on the efflorescence and properties of fly ash based geopolymer[J]. Journal of Cleaner Production2020244: 118852.

    [19] LIU QLI X CCUI M Yet al. Preparation of eco-friendly one-part geopolymers from gold mine tailings by alkaline hydrothermal activation[J]. Journal of Cleaner Production2021298: 126806.

    [20] LI JLIU Y CKE Xet al. Geopolymer synthesized from electrolytic manganese residue and lead-zinc smelting slag: compressive strength and heavy metal immobilization[J]. Cement and Concrete Composites2022134: 104806.

    [21] PUERTAS FPALACIOS MMANZANO Het al. A model for the C-A-S-H gel formed in alkali-activated slag cements[J]. Journal of the European Ceramic Society201131(12): 2043-2056.

    [22] ISHWARYA GSINGH BDESHWAL Set al. Effect of sodium carbonate/sodium silicate activator on the rheologygeopolymerization and strength of fly ash/slag geopolymer pastes[J]. Cement and Concrete Composites201997: 226-238.

    [23] PUERTAS FMARTNEZ-RAMREZ SALONSO Set al. Alkali-activated fly ash/slag cements[J]. Cement and Concrete Research200030(10): 1625-1632.

    [25] KAN L LWANG W SLIU W Det al. Development and characterization of fly ash based PVA fiber reinforced engineered geopolymer composites incorporating metakaolin[J]. Cement and Concrete Composites2020108: 103521.

    [26] XIANG J CLIU L PHE Yet al. Early mechanical properties and microstructural evolution of slag/metakaolin-based geopolymers exposed to karst water[J]. Cement and Concrete Composites201999: 140-150.

    [27] TSUCHIAI HISHIZUKA TUENO Tet al. Highly active absorbent for SO2 removal prepared from coal fly ash[J]. Industrial & Engineering Chemistry Research199534(4): 1404-1411.

    [28] SUN Z QVOLLPRACHT A. Isothermal calorimetry and in situ XRD study of the NaOH activated fly ashmetakaolin and slag[J]. Cement and Concrete Research2018103: 110-122.

    [29] MAHMOOD A HBABAEE MFOSTER S Jet al. Capturing the early-age physicochemical transformations of alkali-activated fly ash and slag using ultrasonic pulse velocity technique[J]. Cement and Concrete Composites2022130: 104529.

    [30] ZHU X YLU C HLI W Ket al. Effects of carbon nanofibers on hydration and geopolymerization of low and high-calcium geopolymers[J]. Cement and Concrete Composites2022133: 104695.

    [31] KAPELUSZNA EKOTWICA RYCKA Aet al. Incorporation of Al in C-A-S-H gels with various Ca/Si and Al/Si ratio: microstructural and structural characteristics with DTA/TGXRDFTIR and TEM analysis[J]. Construction and Building Materials2017155: 643-653.

    [32] LI Y DLI J FCUI Jet al. Experimental study on calcium carbide residue as a combined activator for coal gangue geopolymer and feasibility for soil stabilization[J]. Construction and Building Materials2021312: 125465.

    [33] HAN Y MXIA J WCHANG H Fet al. The influence mechanism of ettringite crystals and microstructure characteristics on the strength of calcium-based stabilized soil[J]. Materials202114(6): 1359.

    [35] GARCA L IMACPHEE D EPALOMO Aet al. Effect of alkalis on fresh C-S-H gels. FTIR analysis[J]. Cement and Concrete Research200939(3): 147-153.

    [36] HE JJIE Y XZHANG J Het al. Synthesis and characterization of red mud and rice husk ash-based geopolymer composites[J]. Cement and Concrete Composites201337: 108-118.

    LAI Jin, LUO Qi, WANG Wenyao, HUANG Wenhao, LIU Fengyue, ZHUANG Rongchuan, WANG Junfeng. Preparation and Properties Characterization of Neutralization Slag Based Geopolymers[J]. Bulletin of the Chinese Ceramic Society, 2023, 42(11): 3978
    Download Citation