Facile Synthesis of Nanoscale CuO and NiO via the PVA-Assisted Sol-Gel Method and Their Exploration in the Catalytic Epoxidation of Styrene

IF 0.7 Q4 ENGINEERING, CHEMICAL

Catalysis in Industry Pub Date : 2025-01-27 DOI:10.1134/S2070050424700211

Ruhul Amin Bepari, Nabajyoti Mochahari, Kibriya Siddique, Birinchi Kumar Das

引用次数: 0

Abstract

Nanoscale oxides of copper and nickel, with diameter 17 and 25 nm respectively, have been synthesized via an easy sol-gel method using polyvinyl alcohol. The method involves the simple dispersion of metal ions (M²⁺ = Cu or Ni) into the PVA gel and subsequent calcination of the dried gel at 400°C for 3 h. The synthesized oxide materials are characterized by different physical tools like TGA, powder XRD, SEM, TEM and DRS UV-visible spectroscopic technique. The oxides are found to be very efficient catalysts in the epoxidation of styrene. CuO gives 87% styrene conversion and 88% SO selectivity while, NiO gives 69% styrene conversion and 80% with TBHP as an oxidant at the end of 6 h. Both the catalysts can suitably be reused for several successive runs without appreciable loss in activity and selectivity. The cost–effective synthesis, excellent catalytic performance and reusability make these oxides promising catalysts for the industrial use.

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pva辅助溶胶-凝胶法快速合成纳米CuO和NiO及其在苯乙烯催化环氧化反应中的应用

以聚乙烯醇为原料，采用溶胶-凝胶法制备了直径分别为17 nm和25 nm的铜和镍纳米氧化物。该方法是将金属离子（M2+ = Cu或Ni）简单分散到PVA凝胶中，然后将干燥的凝胶在400℃下煅烧3小时。合成的氧化物材料通过不同的物理工具，如TGA，粉末XRD， SEM， TEM和DRS紫外可见光谱技术进行表征。这些氧化物在苯乙烯的环氧化反应中是非常有效的催化剂。CuO的苯乙烯转化率为87%，SO选择性为88%，而NiO的苯乙烯转化率为69%，thbhp为氧化剂时的苯乙烯转化率为80%。这两种催化剂都可以连续重复使用几次，而活性和选择性没有明显损失。这些氧化物的合成成本低、催化性能好、可重复使用等优点使其在工业上具有很大的应用前景。

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来源期刊

Catalysis in Industry ENGINEERING, CHEMICAL-

CiteScore

1.30

自引率

14.30%

发文量

期刊介绍： The journal covers the following topical areas: Analysis of specific industrial catalytic processes: Production and use of catalysts in branches of industry: chemical, petrochemical, oil-refining, pharmaceutical, organic synthesis, fuel-energetic industries, environment protection, biocatalysis; technology of industrial catalytic processes (generalization of practical experience, improvements, and modernization); technology of catalysts production, raw materials and equipment; control of catalysts quality; starting, reduction, passivation, discharge, storage of catalysts; catalytic reactors.Theoretical foundations of industrial catalysis and technologies: Research, studies, and concepts : search for and development of new catalysts and new types of supports, formation of active components, and mechanochemistry in catalysis; comprehensive studies of work-out catalysts and analysis of deactivation mechanisms; studies of the catalytic process at different scale levels (laboratory, pilot plant, industrial); kinetics of industrial and newly developed catalytic processes and development of kinetic models; nonlinear dynamics and nonlinear phenomena in catalysis: multiplicity of stationary states, stepwise changes in regimes, etc. Advances in catalysis: Catalysis and gas chemistry; catalysis and new energy technologies; biocatalysis; nanocatalysis; catalysis and new construction materials.History of the development of industrial catalysis.