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铁矿物对偏高岭土基地质聚合物材料抗压强度和微观结构性能的影响。

Effects of Iron Minerals on the Compressive Strengths and Microstructural Properties of Metakaolin-Based Geopolymer Materials.

作者信息

Ngnintedem Dimace Lionel Vofo, Lampe Marco, Tchakouté Hervé Kouamo, Rüscher Claus Henning

机构信息

Laboratory of Analytical Chemistry, Department of Inorganic Chemistry, Faculty of Science, University of Yaounde I, Yaounde P.O. Box 812, Cameroon.

Institut für Mineralogie, Leibniz Universität Hannover, Callinstrasse 3, D-30167 Hannover, Germany.

出版信息

Gels. 2022 Aug 22;8(8):525. doi: 10.3390/gels8080525.

DOI:10.3390/gels8080525
PMID:36005126
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9407464/
Abstract

The current study aims to investigate the influence of iron minerals on the amorphous phase content, compressive strengths and the microstructural properties of the geopolymer materials. Geopolymer materials were prepared by the substitution of metakaolin by 10 and 20 wt.% of each iron mineral sample. Sodium waterglass from rice husk ash was used as a hardener, and metakaolin was used as an aluminosilicate source. The X-ray patterns show that the iron minerals denoted FR and FB are associated with hematite and magnetite, respectively. FY contains goethite together with a significant content of kaolinite and quartz. It is observed in the XRD patterns and FTIR absorption spectra that the additions of hematite, magnetite and goethite remain largely unreacted in the geopolymer binder. The compressive strengths of the related geopolymer composites show some significant variations indicating certain effects for mechanical stability obtained: 10 wt.% replacement of metakaolin by hematite increased the compressive strength from 51.1 to 55.5 MPa, while 20 wt.% hematite caused a decrease to 44.9 MPa. Furthermore, 10 and 20 wt.% replacement with FB revealed decreased values 47.0 and 40.3 MPa, respectively. It was also found that 10 and 20 wt.% of FY caused lower values of 30.9 and 39.1 MPa, respectively. The micrographs of geopolymer materials present some voids and cracks. The denser matrix is related to a superior gel formation producing a better glue between the crystalline additions. The unsubstituted geopolymer sample provides with about 50% the highest X-ray-amorphous content, whereas the substituted samples range between 35 and 45%, indicating systematically smaller gel contents without any clear trend with the compressive strength variation, however. The strength dependencies reveal more complex interaction between the gel and crystalline additions.

摘要

当前研究旨在探究铁矿物对地质聚合物材料非晶相含量、抗压强度及微观结构性能的影响。通过用每种铁矿物样品以10重量%和20重量%替代偏高岭土来制备地质聚合物材料。使用稻壳灰制得的硅酸钠作为硬化剂,偏高岭土用作硅铝酸盐来源。X射线图谱表明,标记为FR和FB的铁矿物分别与赤铁矿和磁铁矿相关。FY含有针铁矿以及大量高岭土和石英。从XRD图谱和FTIR吸收光谱中观察到,赤铁矿、磁铁矿和针铁矿的添加在地质聚合物粘结剂中基本未发生反应。相关地质聚合物复合材料的抗压强度呈现出一些显著变化,表明在机械稳定性方面获得了一定效果:用赤铁矿替代10重量%的偏高岭土使抗压强度从51.1MPa提高到55.5MPa,而20重量%的赤铁矿则使其降至44.9MPa。此外,用FB替代10重量%和20重量%时,抗压强度分别降至47.0MPa和40.3MPa。还发现用FY替代10重量%和20重量%时,抗压强度分别降至30.9MPa和39.1MPa。地质聚合物材料的显微照片显示存在一些孔隙和裂纹。更致密的基体与更优质的凝胶形成相关,从而在晶体添加物之间产生更好的粘结。未被替代的地质聚合物样品具有约50%的最高X射线非晶含量,而被替代的样品含量在35%至45%之间,然而,这表明凝胶含量系统地减少,且与抗压强度变化没有明显趋势。强度依赖性揭示了凝胶与晶体添加物之间更复杂的相互作用。

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