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热催化CO2加氢制乙醇的研究进展

毛瑀中 查飞 田海锋 唐小华 常玥 郭效军

毛瑀中, 查飞, 田海锋, 唐小华, 常玥, 郭效军. 热催化CO2加氢制乙醇的研究进展[J]. 燃料化学学报(中英文), 2023, 51(10): 1514-1528. doi: 10.1016/S1872-5813(22)60065-3
引用本文: 毛瑀中, 查飞, 田海锋, 唐小华, 常玥, 郭效军. 热催化CO2加氢制乙醇的研究进展[J]. 燃料化学学报(中英文), 2023, 51(10): 1514-1528. doi: 10.1016/S1872-5813(22)60065-3
MAO Yu-zhong, ZHA Fei, TIAN Hai-feng, TANG Xiao-hua, CHANG Yue, GUO Xiao-jun. Progress in the thermo-catalytic hydrogenation of CO2 to ethanol[J]. Journal of Fuel Chemistry and Technology, 2023, 51(10): 1514-1528. doi: 10.1016/S1872-5813(22)60065-3
Citation: MAO Yu-zhong, ZHA Fei, TIAN Hai-feng, TANG Xiao-hua, CHANG Yue, GUO Xiao-jun. Progress in the thermo-catalytic hydrogenation of CO2 to ethanol[J]. Journal of Fuel Chemistry and Technology, 2023, 51(10): 1514-1528. doi: 10.1016/S1872-5813(22)60065-3

热催化CO2加氢制乙醇的研究进展

doi: 10.1016/S1872-5813(22)60065-3
基金项目: 国家自然科学基金 (22268039, 21865031)资助
详细信息
    作者简介:

    毛瑀中(1994-),男,硕士研究生,研究方向:能源与环境化工. E-mail:343003568@qq.com

    通讯作者:

    E-mail:zhafei@nwnu.edu.cn

  • 中图分类号: TQ426.94;O643.32

Progress in the thermo-catalytic hydrogenation of CO2 to ethanol

Funds: The project was supported by National Natural Science Foundation of China (22268039, 21865031)
  • 摘要: CO2的化学转化作为碳减排的有效手段受到了广泛关注,近年来,通过热催化工艺将CO2加氢转化为乙醇已经取得了突破性的进展,但仍然存在乙醇选择性及产率低、副产物较多等问题。本工作对热催化CO2加氢制取乙醇的研究进展进行了综述,主要评述了以分子筛、金属氧化物、钙钛矿、二氧化硅、有机框架及金属碳化物等为载体的催化剂应用,分析了不同金属间的协同作用对CO2转化过程的影响以及各类活性物种的介入对于CO2加氢制取乙醇反应的促进作用,总结出能够有效促进C–C键偶联以及CO2吸附和活化的催化剂体系。在此基础上分析了影响CO2加氢制取乙醇的各种因素,并对反应机理进行了讨论。该综述为CO2加氢制备乙醇的催化剂设计、合成工艺条件优化以及催化机理的探究提供参考。
  • FIG. 2711.  FIG. 2711.

    FIG. 2711.  FIG. 2711.

    图  1  CO2加氢合成乙醇原理图 [9]

    Figure  1  Diagram of CO2 hydrogenation to ethanol [9](with permission from Elsevier)

    图  2  合成气通过RhMn@S-1催化合成乙醇 [14]

    Figure  2  Synthesis of ethanol from syngas catalyzed by RhMn@S-1 [14](with permission from Elsevier)

    图  3  Au/α-TiO2上CO2和H2合成乙醇的可能反应途径 [22]

    Figure  3  Possible reaction pathway for the synthesis of ethanol from CO2 and H2 on Au/α-TiO2 catalyst [22](with permission from Copyright Clearance Center)

    图  4  Pd2/CeO2 (110)上催化CO2加氢合成乙醇的过程和活化势垒(红球: O; 蓝球: Pd)[23]

    Figure  4  Process and activation potential for the CO2 hydrogenation to ethanol on the Pd2/CeO2(110) surface[23] (atom coloring: red, O; blue, Pd))(with permission from Elsevier)

    图  5  (a) In2O3和(b) Ir1-In2O3的表面静电势;(c) CO2在In2O3和Ir1-In2O3上的分解自由能 [24]

    Figure  5  Surface electrostatic potential diagram of (a) In2O3 and (b) Ir1-In2O3 surface; (c) free energy diagram of CO2 decomposition on In2O3 and Ir1-In2O3 [24](with permission from American Chemical Society)

    图  6  CZA/K-CMZF多功能催化剂上CO2加氢制乙醇的反应途径及邻近效应[28]

    Figure  6  Reaction pathway and proximity effect for the CO2 hydrogenation to ethanol over the CZA/K-CMZF multifunctional catalyst [28](with permission from American Chemical Society)

    图  7  Co/La4Ga2O9催化CO2加氢合成乙醇反应机理 [32]

    Figure  7  Mechanism of the CO2 hydrogenation to ethanol catalyzed by Co/La4Ga2O9 [32](with permission from Elsevier)

    图  8  CoGa1.0Al1.0O4/SiO2催化剂上CO2加氢合成乙醇 [38]

    Figure  8  CO2 hydrogenation to ethanol over CoGa1.0Al1.0O4/SiO2 catalyst [38](with permission from Elsevier)

    图  9  Cu/SiO2上CO加氢合成甲醇和乙醇的示意图[39]

    Figure  9  Schematic diagram of methanol and ethanol synthesis by CO hydrogenation on the Cu/SiO2 catalyst[39](with permission from John Wiley and Sons)

    图  10  MOF催化CO2加氢合成乙醇机理 [43]

    Figure  10  Mechanism of CO2 hydrogenation to ethanol on MOF-supported catalyst [43](with permission from American Chemical Society)

    图  11  CO2加氢实验装置示意图 [57]

    (A) 固定床反应器,(B) 浆态床反应器,(C) 流化床反应器(1) 原料气瓶,(2) 质量流量控制器,(3) 电加热器,(4) G/L分离器,(5) 冷凝器,(6) 背压调节阀,(7) 湿气量表

    Figure  11  Schematic diagram of different reactor types for the CO2 hydrogenation [57]

    (A) fixed bed reactor, (B) slurry bed reactor and (C) fluidized bed reactor (1) raw gas cylinders, (2) mass flow controller, (3) electric heater, (4) G/L separator, (5) condenser, (6) back pressure control valve, (7) moisture scale(with permission from Elsevier)

    图  12  CO2加氢合成乙醇示意图 [58]

    Figure  12  Schematic diagram of various reactions involved in the CO2 hydrogenation tor ethanol [58](with permission from Elsevier)

    图  13  DFT计算的CO加氢生成甲醇、甲烷和乙醇的反应网络 [63]

    Figure  13  DFT calculated reaction network for the CO hydrogenation to methanol, methane and ethanol [63](with permission from John Wiley and Sons)

    图  14  Fischer-Tropsch反应速率变化示意图 [64]

    Figure  14  Schematic diagram of the Fischer-Tropsch reaction rate change [64](with permission from American Chemical Society)

    图  15  CO2加氢制备醇和碳氢化合物的反应途径[66]

    Figure  15  Reaction pathways for the production of alcohols and hydrocarbons by CO2 hydrogenation[66](with permission from Elsevier)

    图  16  甲醇羰基化制乙醇反应途径[68]

    Figure  16  Reaction pathway of methanol carbonylation to ethanol [68](with permission from American Chemical Society)

    图  17  CO2加氢合成乙醇的机理 [61]

    Figure  17  Mechanism of CO2 hydrogenation to ethanol [61](with permission from Elsevier)

    图  18  DFT计算的C–C偶联反应在(a) Cu/ZnO表面和(b) Cu/Cs/ZnO表面上的势能[72]

    棕色:铜;红色:O;绿色:Cs;灰色:C;白色:H;没有直接参与反应的氧化锌以线型表示

    Figure  18  DFT-calculated potential energy diagram for the C−C coupling reaction on (a) Cu/ZnO and (b) Cu/Cs/ZnO surface [72]

    Cu, brown; O, red; Cs, green; C, gray; H, white; ZnO that did not participate in the reaction directly was represented in line mode(with permission from American Chemical Society)

    表  1  CO2加氢制乙醇工艺条件

    Table  1  Summary of the reaction conditions for the CO2 hydrogenation to ethanol

    CatalystReaction conditionReactor typeEthanol sel. /%CO2
    conv. /%
    Ref.
    p /MPat /℃H2/CO2
    Cu@Na-Beta2.13003∶1fixed bed100.07.9[9]
    RhMn@S-13.03203∶1fixed bed88.3[14]
    RhFeLi/TiO23.02503∶1fixed bed≥30.015.0[18]
    Pd2Cu NPs/P253.22003∶1slurry bed92.0[20]
    LaCo1−xGaxO33.02403∶1fixed bed88.19.8[21]
    Au/TiO26.02003∶1slurry bed98.0[22]
    Ir/In2O36.02005∶1slurry bed99.7[24]
    CZA/K-CMZF5.03203∶1fixed bed≥90.042.3[25]
    Co/La4Ga2O93.02703∶1fixed bed34.74.6[32]
    Rh-Li/SiO25.02403∶1fixed bed15.57.0[33]
    Rh-Fe/SiO25.02603∶1fixed bed16.423.7[34]
    CoGa1.0Al1.0O4/SiO23.02703∶1fixed bed≥80.05.0[38]
    MIL-125-NH2-Cu1-45.01003∶1slurry bed≥90.03.9[43]
    CoMoCx4.01803∶1slurry bed98.4[49]
    K0.2Rh0.2/β-Mo2C6.01503∶1slurry bed72.1[50]
    Pd/Fe3O43.03004∶1fixed bed97.40.3[53]
    CoAlOx4.01403∶1slurry bed92.1[54]
    Co/Mo2C4.02003∶1slurry bed86.025.0[65]
    下载: 导出CSV

    表  2  模型拟合确定的速率常数[64]

    Table  2  Rate constants determined by model fitting[64]

    pCO/mbarRate constant /s −1
    kadskdeskdissktmktkfkbkw
    903.70.0331.300.600.224.1 × 1032.1 × 1030.163
    1373.60.0341.310.520.184.5 × 1032.1 × 1030.135
    1803.40.0361.320.430.164.7 × 1032.2 × 1030.143
    3002.90.0381.390.280.134.7 × 1032.4 × 1030.144
    1202.80.0391.380.190.104.8 × 1032.5 × 1030.148
    9002.60.0421.400.0790.085.1 × 1032.6 × 1030.149
    : (s −1·bar −1)
    下载: 导出CSV
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  • 收稿日期:  2022-09-16
  • 修回日期:  2022-10-08
  • 录用日期:  2022-10-16
  • 网络出版日期:  2022-10-24
  • 刊出日期:  2023-10-10

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