Sajid Iqbal , Sujeong Lee , Ho Jin Ryu , Jong-Il Yun
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引用次数: 0
Abstract
Molybdenum (Mo) tends to form highly mobile, non-sorbing complex redox species, which complicates its immobilization and encapsulation in cement and glass matrices. This study explores the potential of incorporating Mo into an alternative green cementitious material known as geopolymer (GP). By employing X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), X-ray photoelectron spectroscopy (XPS), morphological analysis, and nitrogen adsorption-desorption techniques, we obtained comprehensive insights into the chemical behavior of Mo and its impact on the morphology and structure of the GP matrix. XRD and TGA analysis demonstrated that increasing Mo content significantly enhances the crystallinity and thermal stability of the GP matrix, attributed to Mo field effects. High-resolution SEM, TEM, and EDS mapping revealed the structural encapsulation of Mo-rich cavities within the GP waste form. A decrease in leaching rates with higher Mo content, alongside reduced pore volume and pore size, underscores the material's chemical durability. Post-leaching characterizations confirmed that the GP retains excellent structural strength with minimal changes in mesoporosity and surface area. This resilience highlights the effectiveness of GPs in immobilizing non-sorbing species like MoO32−, making them ideal for long-term waste management.
钼(Mo)倾向于形成高流动性、非吸附性的复合氧化还原物种,这使其在水泥和玻璃基质中的固定和封装变得复杂。本研究探讨了将钼掺入替代性绿色胶凝材料--土工聚合物(GP)--中的可能性。通过采用 X 射线衍射 (XRD)、傅立叶变换红外光谱 (FTIR)、X 射线光电子能谱 (XPS)、形态分析和氮吸附-解吸技术,我们全面了解了钼的化学行为及其对 GP 基体形态和结构的影响。XRD 和 TGA 分析表明,由于钼场效应,钼含量的增加显著提高了 GP 基体的结晶度和热稳定性。高分辨率扫描电子显微镜(SEM)、电子显微镜(TEM)和电子显微析出(EDS)图显示了 GP 废料中富钼空腔的结构封装。钼含量越高,沥滤率越低,同时孔隙体积和孔隙大小也会减小,这突出表明了该材料的化学耐久性。浸出后的表征证实,GP 保持了极佳的结构强度,中孔率和表面积的变化极小。这种韧性凸显了 GP 在固定 MoO32- 等非吸收物种方面的有效性,使其成为长期废物管理的理想材料。
期刊介绍:
Microporous and Mesoporous Materials covers novel and significant aspects of porous solids classified as either microporous (pore size up to 2 nm) or mesoporous (pore size 2 to 50 nm). The porosity should have a specific impact on the material properties or application. Typical examples are zeolites and zeolite-like materials, pillared materials, clathrasils and clathrates, carbon molecular sieves, ordered mesoporous materials, organic/inorganic porous hybrid materials, or porous metal oxides. Both natural and synthetic porous materials are within the scope of the journal.
Topics which are particularly of interest include:
All aspects of natural microporous and mesoporous solids
The synthesis of crystalline or amorphous porous materials
The physico-chemical characterization of microporous and mesoporous solids, especially spectroscopic and microscopic
The modification of microporous and mesoporous solids, for example by ion exchange or solid-state reactions
All topics related to diffusion of mobile species in the pores of microporous and mesoporous materials
Adsorption (and other separation techniques) using microporous or mesoporous adsorbents
Catalysis by microporous and mesoporous materials
Host/guest interactions
Theoretical chemistry and modelling of host/guest interactions
All topics related to the application of microporous and mesoporous materials in industrial catalysis, separation technology, environmental protection, electrochemistry, membranes, sensors, optical devices, etc.
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