Modern Methods for Producing Acetic Acid from Methane: New Trends (A Review)

被引:12
作者
Ezhova, N. N. [1 ]
Kolesnichenko, N., V [1 ]
Maximov, A. L. [1 ]
机构
[1] Russian Acad Sci, Topchiev Inst Petrochem Synth, Moscow 119991, Russia
来源
PETROLEUM CHEMISTRY | 2022年 / 62卷 / 01期
基金
俄罗斯科学基金会;
关键词
synthesis of acetic acid from methane over heterogeneous catalysts; synthesis of acetic acid via syngas; low-temperature" oxidative methane conversion; one- and two-step procedures for methane conversion to acetic acid; direct synthesis of acetic acid from methane and carbon dioxide; DIMETHYL ETHER CARBONYLATION; FISCHER-TROPSCH SYNTHESIS; CARBON-DIOXIDE; DIRECT CONVERSION; ZEOLITE CATALYST; METHYL ACETATE; AROMATIC-HYDROCARBONS; EFFICIENT CATALYSTS; COMPOSITE ZEOLITE; DIRECT OXIDATION;
D O I
10.1134/S0965544122010078
中图分类号
O62 [有机化学];
学科分类号
070303 ; 081704 ;
摘要
Recent achievements in the development of new methods for producing acetic acid (AA) from methane using heterogeneous catalysts are summarized and systematized Modern heterogeneous-catalytic processes of methane conversion to AA via syngas and alternative one- and two-step AA production procedures via "low-temperature" oxidative methane conversion (via oxidative coupling, oxyhalogenation, oxidation into methanol, or oxidative transformations of CH4 in the presence of carbon oxides) are considered. The major attention is paid to the one-step AA synthesis by methane oxydation with carbon dioxide (by carboxylation reaction). Specific features of heterogeneous catalysts recently developed for this reaction are discussed.
引用
收藏
页码:40 / 61
页数:22
相关论文
共 187 条
[1]  
Aldoshin S.M., 2015, NEFTEGAZOKHIMIYA, P60
[2]   New Trends in Olefin Production [J].
Amghizar, Ismael ;
Vandewalle, Laurien A. ;
Van Geem, Kevin M. ;
Marin, Guy B. .
ENGINEERING, 2017, 3 (02) :171-178
[3]  
Armitage G.G., 2013, Patent US, Patent No. 8431732
[4]  
Arutyunov V, 2014, DIRECT METHANE TO METHANOL: FOUNDATIONS AND PROSPECTS OF THE PROCESS, P1
[5]   Prospects of Conversion of Hydrocarbon Gases to Liquid Products Based on Nitrogen-Rich Synthesis Gas [J].
Arutyunov, V. S. ;
Strekova, L. N. ;
Savchenko, V. I. ;
Sedov, I. V. ;
Nikitin, A. V. ;
Eliseev, O. L. ;
Kryuchkov, M. V. ;
Lapidus, A. L. .
PETROLEUM CHEMISTRY, 2019, 59 (04) :370-379
[6]   Effect of Zeolite on Fischer-Tropsch Synthesis in the Presence of a Catalyst Based on Skeletal Cobalt [J].
Asalieva, E. Yu. ;
Kul'chakovskaya, E. V. ;
Sineva, L. V. ;
Mordkovich, V. Z. .
PETROLEUM CHEMISTRY, 2020, 60 (01) :69-74
[7]   Oxidative coupling of methane over mixed metal oxide catalysts: Steady state multiplicity and catalyst durability [J].
Aseem, A. ;
Jeba, Geofrey Goldwin ;
Conato, Marlon T. ;
Rimer, Jeffrey D. ;
Harold, Michael P. .
CHEMICAL ENGINEERING JOURNAL, 2018, 331 :132-143
[8]  
Backer M.J., 1997, European Patent, Patent No. 0752406
[9]  
Baker M. J., 2000, European Patent, Patent No. 0749948
[10]   Significant Advances in C1 Catalysis: Highly Efficient Catalysts and Catalytic Reactions [J].
Bao, Jun ;
Yang, Guohui ;
Yoneyama, Yoshiharu ;
Tsubaki, Noritatsu .
ACS CATALYSIS, 2019, 9 (04) :3026-3053
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