将纳米和微米二氧化硅作为偏高岭土磷酸盐土工聚合物的补充添加剂应用于陶瓷应用--微米和纳米结构研究

IF 3.4 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY International Journal of Mechanical and Materials Engineering Pub Date : 2024-09-26 DOI:10.1186/s40712-024-00176-6
N. Vanitha, Rithikaa Thanigaiselvan, M. Manivannan, R. Jeyalakshmi, S. N. Megha, M. Kesavan
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引用次数: 0

摘要

由聚磷酸硅氧单元组成的偏高岭磷酸盐土工聚合物因其结构性能而闻名,此外,在高温条件下,其微观结构也会随着结晶贝氏体相的转变而发生变化。偏高岭土的铝在酸中的固有反应已被开发利用,但对二氧化硅次生相的反应却知之甚少。以偏高岭土为主要前驱体(M),添加 2% 和 5% 的纳米二氧化硅(MS2 和 MS5)和微量二氧化硅(MM2 和 MM5),使用 8-M 磷酸浇铸,在 80 °C 下固化。为了提高土工聚合物在高温应用中的利用率,研究人员通过 XRD、拉曼、TGA-DTA、扫描电镜、XPS、傅立叶变换红外光谱和 MAS-NMR 对加热到不同温度(200、400、600 和 800 ℃)后的结构转变进行了研究。样品 M 的强度从 46.2 兆帕提高到 MS5 的 63.6 兆帕和 MM5 的 54.2 兆帕。这可归因于拉曼光谱带中 Si-O-Al-O-Si 转变为 Si-O-Al-O-P 的结果。将 Al (IV) 的化学位移与对照组进行比较,发现微量二氧化硅的加入使信号转移到了较低的区域(53 至 50 ppm),这与 Al 连接的 Si 数量增加以形成更坚韧的网络有关。纳米压痕可从硬度和弹性直观地看出,硅增强样品在 20 至 100 mN 负荷下的相应值为 1.4 至 2.1 GPa 和 0.8 至 1.4 GPa,远高于 M。TGA-DTA 显示,对照组的质量损失减少了 25.4%,而 MS5 减少了 17.2%,MM5 减少了 15.8%。此外,在 25 至 1000 °C 的整个温度范围内,MS5 和 MM5 的收缩率分别低至 - 1.1% 和 - 0.8%,从而为使用纳米和微米形式的二氧化硅提供了更好的耐热性能。
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Expounding the application of nano and micro silica as a complementary additive in metakaolin phosphate geopolymer for ceramic applications—micro and nanoscale structural investigation

Metakaolin phosphate geopolymers comprising poly-phospho-siloxo units are known for their structural performance, additionally advancing their microstructure with the transformation of crystalline berlinite phases at elevated temperatures. The intrinsic reaction of Al of metakaolin in the acid exploited, but the reaction of secondary silica phases is limitedly known. Metakaolin as a primary precursor (M) with the addition of 2% and 5% of nano silica (MS2 and MS5) and micro silica (MM2 and MM5) cast using 8-M phosphoric acid was cured at 80 °C. To enhance the utilization of geopolymer in any high-temperature applications, the structural transformations were studied after heating to various temperatures (200, 400, 600 and 800 °C) by XRD, Raman, TGA-DTA, SEM, XPS, FTIR and MAS-NMR. Sample M attained a strength of 46.2 MPa enhanced to 63.6 MPa in MS5 and 54.2 MPa in MM5. This can be ascribed from the transformation of Si–O–Al–O–Si into Si–O–Al–O–P from Raman bands. Comparing the chemical shift of Al (IV) to control, micro silica addition shifts the signal to a lower field (53 to 50 ppm) related to the increase of the number of Al-connected Si to give a tougher network. Nanoindentation is visualized from hardness and elasticity, and the corresponding values are 1.4 to 2.1 GPa and 0.8 to 1.4 GPa for loads ranging from 20 to 100 mN in silica-reinforced samples that are much higher than M. The micro and macro hardness is due to the reinforcement of quartz in micro silica around the gel. TGA-DTA showed that the reduction of mass loss is as high as 25.4% in control whereas 17.2% in MS5 and 15.8% in the MM5. Further, shrinkage rate in MS5 and MM5 was as low as − 1.1% and − 0.8% throughout the temperature range from 25 to 1000 °C and thus provides the way of use of nano and micro form of silica for better thermal resistance.

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