用于增强铅蒸气捕获的水热法合成高岭土类片状/海绵状铝硅酸盐。

Journal of hazardous materials Pub Date : 2024-10-05 Epub Date: 2024-08-13 DOI:10.1016/j.jhazmat.2024.135509
Tengfei He, Zifeng Luo, Baosheng Jin
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引用次数: 0

摘要

开发具有优异多孔特性的耐高温吸附剂对于通过热解安全处理含重金属固体废物至关重要。我们通过水热法合成了铝硅酸盐,并观察到酸性条件(尤其是盐酸(pH=2.6))有利于海绵状矿物(NC2.6)的形成,其比表面积为 500.31 m²/g,孔隙体积为 0.986 cm³ /g,而碱性条件(pH=12.0)则促进了球形颗粒的生长。与高岭石和哈洛石相比,NC2.6 在 PbCl2 蒸汽吸附中表现出更高的吸附容量,在 700 ℃ 时达到最大值 137.68 mg/g(75.91 % 稳定)。我们利用 DFT 和 GCMC 模拟研究了 CO2 和 H2O 对吸附效率的影响,并探讨了其中的机理。从 GCMC 结果来看,由于竞争性吸附,CO2 对 PbCl2 的吸附产生了负面影响,而 H2O 则通过将 PbCl2 转化为氧化物增加了吸附含量(700 ℃ 时为 144.24 mg/g)。DFT 发现,CO2 的存在通过在 CO2 中的 O 与 Pb 之间形成共价键以及在铝硅酸盐表面形成活性 O,增强了 PbCl2 的吸附稳定性。H2O 增加了 PbCl2 的吸附能,因为 H2O 中的 O 占据了原本与 Cl 形成共价键的活性 Al,而 H 则与 Cl 形成了弱氢键。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hydrothermal synthesized kaolin group lamellar/spongy aluminosilicates for enhanced lead vapor capture.

Developing high-temperature-resistant adsorbents with superior porous properties is crucial for safely disposing of heavy metal-containing solid waste via pyrolysis. We synthesized aluminosilicates hydrothermally and observed that acidic conditions, especially HCl (pH=2.6), favored sponge-like mineral (NC2.6) formation with a specific surface area of 500.31 m²/g and pore volume of 0.986 cm³ /g, while alkaline conditions (pH=12.0) promoted spherical particle growth. NC2.6 exhibited higher adsorption capacity compared to kaolinite and halloysite in the PbCl2 vapor adsorption, reaching a maximum of 137.68 mg/g at 700 ℃ (75.91 % stable). We examined the effect of CO2 and H2O on adsorption efficiency and explored the mechanisms using DFT and GCMC simulations. From GCMC results, CO2 negatively impacted PbCl2 adsorption due to competitive adsorption, while H2O increased adsorption content (144.24 mg/g at 700 ℃) by converting PbCl2 into oxides. DFT revealed the presence of CO2 enhanced the adsorption stability of PbCl2 via the formation of covalent bonds between O in CO2 and Pb, and active O on the aluminosilicate surface. H2O increased PbCl2 adsorption energy, as O in H2O occupied an active Al that originally formed a covalent bond with Cl, while the H formed a weak hydrogen bond with this Cl.

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