Synthesis and studies of advanced adsorbent zeolites by using red mud and rice husk ash as a thermal insulation agent

IF 1.827 Q2 Earth and Planetary Sciences

Arabian Journal of Geosciences Pub Date : 2025-04-07 DOI:10.1007/s12517-025-12241-1

Kamna Chaturvedi, Manish Dhangar, Medha Mili, Avanish Kumar Srivastava, Sarika Verma

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Abstract

The advanced zeolite-based adsorbent for thermal insulating material is synthesized by using red mud and rice husk ash for sustainable waste management and energy-efficient building solutions. The process involves alkaline integration accompanied by a method with a step change in temperature. The synthesized zeolites were characterized by using all the standard techniques along with (thermal conductivity. The X-ray Diffraction analysis revealed key phases including gonnardite, jadeite, and albite, confirming the formation of zeolite structures that contribute to the material’s thermal insulating properties. The more porous nature of the material also confirms its properties as a thermally insulating material by microstructure analysis. The Infrared spectra also confirm the stretching and bending frequencies of the prepared material. The Brunauer-Emmett-Teller (BET) analysis confirms the pore size distribution which shows that the developed sample is highly porous. The results show a value of average pore volume of 0.019 cc/g, a pore width of 4.903 nm, a surface area of 10.564 m²/g, and BET area of 9.842 m²/g. The thermal conductivity of SET 3 is as low as 0.16 W/mK and proves that it is a thermal insulator. The synthesis of zeolites from industrial waste not only provides an environmentally friendly solution and responsible waste management but also meets the increasing demand for thermal insulating materials. The findings emphasize the dual role of red mud and rice husk ash in the production of zeolite-based thermal insulating materials with potential adsorption properties, contributing to sustainable waste management and energy-efficient building solutions.

Graphical abstract

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以赤泥和稻壳灰为绝热剂的高级吸附剂沸石的合成与研究

采用赤泥和稻壳灰合成先进的沸石基保温材料吸附剂，用于可持续废物管理和节能建筑解决方案。该过程包括碱性集成，并伴有温度阶跃变化的方法。采用各种标准技术及热导率对合成的沸石进行了表征。x射线衍射分析揭示了关键相，包括gonnarite，翡翠和钠长石，证实了沸石结构的形成，有助于材料的隔热性能。通过微观结构分析，材料的多孔性也证实了其作为隔热材料的性能。红外光谱也证实了所制备材料的拉伸和弯曲频率。brunauer - emmet - teller （BET）分析证实了发育样品的孔隙大小分布，表明发育样品具有高孔隙性。结果表明，平均孔隙体积为0.019 cc/g，孔径为4.903 nm，比表面积为10.564 m2/g， BET面积为9.842 m2/g。SET 3的导热系数低至0.16 W/mK，证明它是一种隔热材料。从工业废料中合成沸石不仅提供了一种环保的解决方案和负责任的废物管理，而且满足了对隔热材料日益增长的需求。研究结果强调了赤泥和稻壳灰在生产具有潜在吸附性能的沸石基隔热材料中的双重作用，有助于可持续废物管理和节能建筑解决方案。图形抽象

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来源期刊

Arabian Journal of Geosciences GEOSCIENCES, MULTIDISCIPLINARY-

自引率

0.00%

发文量

1587

审稿时长

6.7 months

期刊介绍： The Arabian Journal of Geosciences is the official journal of the Saudi Society for Geosciences and publishes peer-reviewed original and review articles on the entire range of Earth Science themes, focused on, but not limited to, those that have regional significance to the Middle East and the Euro-Mediterranean Zone. Key topics therefore include; geology, hydrogeology, earth system science, petroleum sciences, geophysics, seismology and crustal structures, tectonics, sedimentology, palaeontology, metamorphic and igneous petrology, natural hazards, environmental sciences and sustainable development, geoarchaeology, geomorphology, paleo-environment studies, oceanography, atmospheric sciences, GIS and remote sensing, geodesy, mineralogy, volcanology, geochemistry and metallogenesis.