L. N. Stepanova, R. Mironenko, O. Belskaya, V. Likholobov
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引用次数: 2
摘要
摘要:本研究采用机械化学方法合成lial层状双氢氧化物(LDHs)。这种方法是环保的,可以在相对温和的条件下(铣削体的向心加速度为300 m s-2)和较短的时间内(15分钟)获得LiAl-LDH。用x射线衍射证实了所制备的LiAl-LDH、lial -混合氧化物(煅烧的LDH)和相应混合氧化物再水化后得到的活化的LiAl-LDH的结构。采用程序升温解吸法和双等温线法测定了LiAlOx的碱度。结果表明,与常规共沉淀法制备的mgalo混合氧化物相比,lial混合氧化物对二氧化碳的吸附能力显著提高。这表明在含锂体系中存在大量不同强度(强、中、弱)的基本表面位点。具有Bronsted碱基(层间空间中的OH基团)的活化LiAl-LDH的形成使LiAlOx在糠醛和丙酮之间的水相醛醇缩合反应中的催化活性增加。
Mechanochemically synthesized LiAlOx catalyst for aqueous aldol condensation of furfural with acetone
Abstract In the present study, the mechanochemical method is proposed for synthesis of LiAl-layered double hydroxides (LDHs). This method is eco-friendly and allows obtaining LiAl-LDH under relatively mild conditions (centripetal acceleration of milling bodies 300 m s-2) and in a short period of time (15 minutes). The structures of as-prepared LiAl-LDH, LiAl-mixed oxide (calcined LDH) and “activated” LiAl-LDH obtained after rehydration of the corresponding mixed oxide were confirmed by X-ray diffraction. The basicity of LiAlOx was measured by temperature-programmed desorption of CO2 and double isotherm technique. According to data obtained, LiAl-mixed oxide has a significant higher carbon dioxide adsorption capacity compared to MgAlmixed oxides prepared by conventional co-precipitation method. This indicates a large amount of basic surface sites with different strength (strong, medium and weak) for Li-containing systems. The formation of “activated” LiAl-LDH having Bronsted basic sites (OH groups in the interlayer space) provides an increased catalytic activity of LiAlOx in the reaction of aqueous-phase aldol condensation between furfural and acetone.
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