常压下氧在VAlPO4沸石上高选择性氧化环己烷生成环己酮和环己醇。

Q1 Chemistry
Yun Hong, Dalei Sun, Yanxiong Fang
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引用次数: 18

摘要

背景:环己烷在温和条件下的氧化反应在化学工业中占有重要地位。几种可溶过渡金属作为均相催化剂广泛应用于环己烷的工业氧化。由于多相催化剂在分离和回收方面比均相催化剂更易于管理,因此在本研究中,我们采用水热合成的方法,将纯白沸石(AlPO4)和含钒白沸石(VAlPO4)作为多相催化剂,在常压下用分子氧选择性氧化环己烷。采用XRD、FT-IR、XPS和SEM对催化剂进行了表征。对溶剂种类、反应温度、反应时间等影响因素进行了系统的研究。结果:通过XRD表征,确定了AlPO4和VAlPO4催化剂均具有berlinite结构。FT-IR结果证实了VAlPO4的berlinite框架中含有钒。XPS测量结果表明,VAlPO4结构中的氧离子比V2O5结构中的氧离子具有更高的结合能,因此在VAlPO4催化剂表面存在晶格氧。结果表明,常压条件下,AlPO4能催化环己烷与分子氧的选择性氧化,而AlPO4则无活性。在最佳反应条件下(100 mL环己烷,0.1 MPa O2, 353 K, 4 h, 5 mg VAlPO4和20 mL乙酸溶剂),KA油(环己醇和环己酮)的选择性高达97.2%(环己烷转化率近6.8%)。基于这些结果,提出了环己烷在VAlPO4上选择性氧化的可能机理。结论:作为一种多相催化剂,VAlPO4对环己烷与分子氧的选择性氧化具有高活性和强稳定性。我们提出KA油是通过催化循环形成的,其中包括环己烷被一个关键的活性中间物质激活,由环己烷中的晶格氧离子与碳的亲核加成形成,以及在VAlPO4催化剂表面形成氧空位。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The highly selective oxidation of cyclohexane to cyclohexanone and cyclohexanol over VAlPO<sub>4</sub> berlinite by oxygen under atmospheric pressure.

The highly selective oxidation of cyclohexane to cyclohexanone and cyclohexanol over VAlPO<sub>4</sub> berlinite by oxygen under atmospheric pressure.

The highly selective oxidation of cyclohexane to cyclohexanone and cyclohexanol over VAlPO<sub>4</sub> berlinite by oxygen under atmospheric pressure.

The highly selective oxidation of cyclohexane to cyclohexanone and cyclohexanol over VAlPO4 berlinite by oxygen under atmospheric pressure.

Background: The oxidation of cyclohexane under mild conditions occupies an important position in the chemical industry. A few soluble transition metals were widely used as homogeneous catalysts in the industrial oxidation of cyclohexane. Because heterogeneous catalysts are more manageable than homogeneous catalysts as regards separation and recycling, in our study, we hydrothermally synthesized and used pure berlinite (AlPO4) and vanadium-incorporated berlinite (VAlPO4) as heterogeneous catalysts in the selective oxidation of cyclohexane with molecular oxygen under atmospheric pressure. The catalysts were characterized by means of by XRD, FT-IR, XPS and SEM. Various influencing factors, such as the kind of solvents, reaction temperature, and reaction time were investigated systematically.

Results: The XRD characterization identified a berlinite structure associated with both the AlPO4 and VAlPO4 catalysts. The FT-IR result confirmed the incorporation of vanadium into the berlinite framework for VAlPO4. The XPS measurement revealed that the oxygen ions in the VAlPO4 structure possessed a higher binding energy than those in V2O5, and as a result, the lattice oxygen was existed on the surface of the VAlPO4 catalyst. It was found that VAlPO4 catalyzed the selective oxidation of cyclohexane with molecular oxygen under atmospheric pressure, while no activity was detected on using AlPO4. Under optimum reaction conditions (i.e. a 100 mL cyclohexane, 0.1 MPa O2, 353 K, 4 h, 5 mg VAlPO4 and 20 mL acetic acid solvent), a selectivity of KA oil (both cyclohexanol and cyclohexanone) up to 97.2% (with almost 6.8% conversion of cyclohexane) was obtained. Based on these results, a possible mechanism for the selective oxidation of cyclohexane over VAlPO4 was also proposed.

Conclusions: As a heterogeneous catalyst VAlPO4 berlinite is both high active and strong stable for the selective oxidation of cyclohexane with molecular oxygen. We propose that KA oil is formed via a catalytic cycle, which involves activation of the cyclohexane by a key active intermediate species, formed from the nucleophilic addition of the lattice oxygen ion with the carbon in cyclohexane, as well as an oxygen vacancy formed at the VAlPO4 catalyst surface.

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来源期刊
Chemistry Central Journal
Chemistry Central Journal 化学-化学综合
CiteScore
4.40
自引率
0.00%
发文量
0
审稿时长
3.5 months
期刊介绍: BMC Chemistry is an open access, peer reviewed journal that considers all articles in the broad field of chemistry, including research on fundamental concepts, new developments and the application of chemical sciences to broad range of research fields, industry, and other disciplines. It provides an inclusive platform for the dissemination and discussion of chemistry to aid the advancement of all areas of research. Sections: -Analytical Chemistry -Organic Chemistry -Environmental and Energy Chemistry -Agricultural and Food Chemistry -Inorganic Chemistry -Medicinal Chemistry -Physical Chemistry -Materials and Macromolecular Chemistry -Green and Sustainable Chemistry
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