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光催化甲烷转化研究进展
作者单位:
基金项目:the National Natural Science Foundation of China(21876114);the National Natural Science Foundation of China(21761142011);the National Natural Science Foundation of China(51572174);Shanghai Government, China(19160712900);International Joint Laboratory on Resource Chemistry, China (IJLRC), and the Program for Professor of Special Appointment (Eastern Scholar) at Shanghai Institutions of Higher Learning, China
摘    要:甲烷催化转化为高附加值产物、实现甲烷高效利用,具有重要的研究意义及工业应用价值。长期以来,如何在较温和的条件下将甲烷转化为其它更有价值的有机衍生物,如醇、芳烃、长链烷烃和烯烃等,是催化、化学及化工领域的热点和难点课题之一。光催化反应由光能激发产生光生电子和空穴,参与到甲烷C―H键活化和自由基形成,这为低温甲烷转化提供新的途径,本文主要围绕甲烷氧化和偶联反应,总结了近年来光催化研究进展,并对如何进一步提高光催化性能提出展望。

关 键 词:光催化  甲烷转化  氧化制甲醇  无氧偶联  氧化偶联  
收稿时间:2019-07-01

Photocatalytic Methane Conversion
Zhenmin Xu,Zhenfeng Bian. Photocatalytic Methane Conversion[J]. Acta Physico-Chimica Sinica, 2020, 36(3): 1907013-0. DOI: 10.3866/PKU.WHXB201907013
Authors:Zhenmin Xu  Zhenfeng Bian
Affiliation:
Abstract:Methane is a promising energy source with vast reserves, and is considered one of the promising alternatives to nonrenewable petroleum resources because it can be converted into valuable hydrocarbon feedstocks and hydrogen through appropriate reactions. Recently, the conversion of CH4 into other high-value-added products has received increasing attention because of their sustainability for energy and the environment. However, methane has a tetrahedral geometry with four equivalent C―H bonds due to the sp3 hybridization of the central carbon atom, with a C―H bond length of 0.1087 nm and an H-C―H bond angle of 109.5°. The absence of a dipole moment and the small polarizability (2.84 × 10−40 C2·m2·J−1) imply that methane requires a high local electric field for polarization and for nucleophilic or electrophilic attack. Nevertheless, it is believed that an effective method to activate CH4 would be available, so that not only methanol, formaldehyde, and ethylene but also other industrially valuable raw materials can be obtained. On the other hand, the conversion of this combustible gas into the corresponding liquid fossil fuel proceeds via secondary chemical conversion, and it can greatly reduce transportation costs. From the economic viewpoint, this can still provide considerable benefits. Homogeneous catalysts have been reported to catalyze methane, but most of them operate at high pressures (2–7 MPa), or in strongly acidic media and at high temperatures (up to 500 K). Heterogeneous catalysts reported in the literature are also active only at high temperatures. Therefore, finding an efficient method to active methane has become a hot research topic. Photocatalysis technology is recognized as the optimal solution for the conversion of CH4 since solar energy is by far the largest exploitable resource of energy. In the past years, much effort has been undertaken for the conversion of CH4 under light at low temperature. In this regard, several photocatalysts, including silica-alumina-titania, silica-supported oxides, and ceria- and zeolite-based materials, have been developed. In photocatalytic methane conversion, the C―H bond can be selectively activated by adjusting the wavelength and intensity of the incident light and the oxidation capacity of the photocatalysts, thereby avoiding the formation of byproducts. This review summarizes a series of photocatalytic direct methane conversion systems developed in recent years, including methane oxidation and coupling processes. The effects of the catalyst composition and structure, oxidant, and electron transfer on the activation of the C―H bond of methane are detailed. Finally, future perspectives and challenges for the photocatalytic conversion of methane are discussed.
Keywords:Photocatalysis  Methane conversion  Oxidation to methanol  Anaerobic coupling  Oxidative coupling  
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