Advances in Fe-based catalysts for conversion of syngas/CO2 to higher alcohols

doi:10.16085/j.issn.1000-6613.2024-0472

Abstract

Abstract:

The synthesis of higher alcohols is a significant approach for converting non-petroleum resources like coal, natural gas, biomass, CO/CO₂, and others into liquid fuels and high-valued chemicals, which holds great importance in promoting the clean and efficient utilization of coal and CO₂. In recent years, there have been remarkable achievements in the research of modified Fischer-Tropsch synthesis catalysts for higher alcohol synthesis, giving significant enhancements in catalytic performance and selectivity for higher alcohols. Fe-based catalysts have emerged as a research focus in recent years due to their low cost and easy access, and their reaction mechanisms can be drawn upon that of Fischer-Tropsch synthesis. However, basic theoretical research still requires to be strengthened. This article presents an overview of the latest research progress on Fe-based catalysts, with a particular emphasis on the properties and reaction mechanisms of active sites in the synthesis of higher alcohols using Fe-based and FeCu-based catalysts. This article reviews the impact of alkali metals, transition metal additives, and non-metallic doping on the structure-activity relationship of catalysts, as well as on enhancing the catalytic activity, higher alcohol selectivity, and catalyst stability. Comparisons were made for commonly used carriers such as SiO₂ and Al₂O₃. A systematic analysis of the preparation methods of Fe-based catalysts is presented in terms of the impregnation method, special structure design, and material composite.

Key words: alcohol, catalyst, adsorption, reactivity, selectivity, support

摘要：

合成高级醇是将煤、天然气、生物质、CO/CO₂等非石油资源转化为液体燃料和高附加值化学品的重要途径之一，对推动煤炭清洁高效利用、CO₂资源化利用具有重要意义。近年来，通过改性费托合成催化剂来合成高级醇的研究取得了重要进展，催化剂性能明显提升。因材料廉价易获取且反应机理可借鉴费托合成，Fe基催化剂成为研究热点，但基础理论研究仍待完善。本文概述了近期高级醇合成Fe基催化剂最新的研究进展，重点综述了Fe基催化剂、FeCu基催化剂在合成高级醇反应中活性位点的性质和反应机理。梳理了碱金属、过渡金属、非金属改性对催化剂构效关系的影响，及其对提高催化剂催化活性、高级醇选择性、稳定性的作用。对比了SiO₂、Al₂O₃等常用载体的作用。按浸渍法、特殊结构、复合材料等分别对Fe基催化剂制备方法进行了系统性剖析。

关键词: 醇, 催化剂, 吸附, 活性, 选择性, 载体

CLC Number:

TQ519

ZHANG Qi, WANG Tao, ZHANG Xuebing, LI Weizhen, CHENG Meng, ZHANG Kui, LYU Yijun, MEN Zhuowu. Advances in Fe-based catalysts for conversion of syngas/CO₂ to higher alcohols[J]. Chemical Industry and Engineering Progress, 2025, 44(3): 1323-1337.

张琪, 王涛, 张雪冰, 李为真, 程萌, 张魁, 吕毅军, 门卓武. 合成气/CO₂转化制高级醇Fe基催化剂研究进展[J]. 化工进展, 2025, 44(3): 1323-1337.

Figures/Tables 12

References 95

1	Ho Ting LUK, MONDELLI Cecilia, FERRÉ Daniel Curulla, et al. Status and prospects in higher alcohols synthesis from syngas[J]. Chemical Society Reviews, 2017, 46(5): 1358-1426.
2	曾壮, 李柯志, 苑志伟, 等. CO/CO₂加氢制低碳醇改性费托合成催化剂研究进展[J]. 化工进展, 2024, 43(6)： 3061-3079.
	ZENG Zhuang, LI Kezhi, YUAN Zhiwei, et al. Advances in modified Fischer-Tropsch synthesis catalysts for CO/CO₂ hydrogenation to higher alcohols[J]. Chemical Industry and Engineering Progress, 2024, 43(6)： 3061-3079.
3	HU Jingting, WEI Zeyu, ZHANG Yunlong, et al. Edge-rich molybdenum disulfide tailors carbon-chain growth for selective hydrogenation of carbon monoxide to higher alcohols[J]. Nature Communications, 2023, 14(1): 6808.
4	AO Min, PHAM Gia Hung, SUNARSO Jaka, et al. Active centers of catalysts for higher alcohol synthesis from syngas: A review[J]. ACS Catalysis, 2018, 8(8): 7025-7050.
5	刘瑞琴, 孟凡会, 王立言, 等. 有序介孔CuCoZr催化剂的制备及其催化合成气制乙醇及高级醇性能[J]. 化工进展, 2022, 41(11): 5870-5878.
	LIU Ruiqin, MENG Fanhui, WANG Liyan, et al. Preparation of ordered mesoporous CuCoZr catalyst and its catalytic performance for syngas to ethanol and higher alcohols[J]. Chemical Industry and Engineering Progress, 2022, 41(11): 5870-5878.
6	BORSHCH Vyacheslav N, ZHUK Svetlana Ya, PUGACHEVA Elena V, et al. Co-Cu-La catalysts for selective CO₂ hydrogenation to higher hydrocarbons[J]. Mendeleev Communications, 2023, 33(1): 55-57.
7	GUAN Zun, ZHAO Wantong, LI Debao, et al. The new role of pivotal intermediate CH _x in CO activation and conversion to hydrocarbons on the transition metal catalysts[J]. Fuel, 2023, 331: 125788.
8	ZHANG Shunan, HUANG Chaojie, SHAO Zilong, et al. Revealing and regulating the complex reaction mechanism of CO₂ hydrogenation to higher alcohols on multifunctional tandem catalysts[J]. ACS Catalysis, 2023, 13(5): 3055-3065.
9	GUO Shaoxia, LI Zhuoshi, YIN Rui, et al. Oxygen vacancy over CoMnO _x catalysts boosts selective ethanol production in the higher alcohol synthesis from syngas[J]. ACS Catalysis, 2023, 13(21): 14404-14414.
10	XU Di, WANG Yanqiu, DING Mingyue, et al. Advances in higher alcohol synthesis from CO₂ hydrogenation[J]. Chem, 2021, 7(4): 849-881.
11	孔祥宇, 谢亮, 王延民, 等. CO₂的捕集及资源化利用[J]. 化工进展, 2022, 41(3): 1187-1198.
	KONG Xiangyu, XIE Liang, WANG Yanmin, et al. CO₂ capture and resource utilization[J]. Chemical Industry and Engineering Progress, 2022, 41(3): 1187-1198.
12	LATSIOU Angeliki I, CHARISIOU Nikolaos D, FRONTISTIS Zacharias, et al. CO₂ hydrogenation for the production of higher alcohols: Trends in catalyst developments, challenges and opportunities[J]. Catalysis Today, 2023, 420: 114179.
13	NING Shangbo, Honghui OU, LI Yaguang,et al. Co⁰-Co ^δ ⁺ interface double-site-mediated C—C coupling for the photothermal conversion of CO₂ into light olefins[J]. Angewandte Chemie International Edition, 2023, 62(23): e202302253.
14	LI Haobo, WU Donghai, WU Jiarui, et al. Mechanistic understanding of the electrocatalytic conversion of CO into C₂₊ products by double-atom catalysts[J]. Materials Today Physics, 2023, 37: 101203.
15	XIONG Haifeng, JEWELL Linda L, COVILLE Neil J. Shaped carbons as supports for the catalytic conversion of syngas to clean fuels[J]. ACS Catalysis, 2015, 5(4): 2640-2658.
16	DE SMIT Emiel, WECKHUYSEN Bert M. The renaissance of iron-based Fischer-Tropsch synthesis: On the multifaceted catalyst deactivation behaviour[J]. Chemical Society Reviews, 2008, 37(12): 2758-2781.
17	GAUBE J, H-F KLEIN. Studies on the reaction mechanism of the Fischer-Tropsch synthesis on iron and cobalt[J]. Journal of Molecular Catalysis A: Chemical, 2008, 283(1/2): 60-68.
18	VAN SANTEN Rutger A, GHOURI Minhaj, HENSEN Emiel M J. Microkinetics of oxygenate formation in the Fischer-Tropsch reaction[J]. Physical Chemistry Chemical Physics, 2014, 16(21): 10041-10058.
19	PHAM Thanh Hai, QI Yanying, YANG Jia, et al. Insights into Hägg iron-carbide-catalyzed Fischer-Tropsch synthesis: Suppression of CH₄ formation and enhancement of C—C coupling on χ-Fe₅C₂(510)[J]. ACS Catalysis, 2015, 5(4): 2203-2208.
20	XU Jing, WEI Jian, ZHANG Jixin, et al. Highly selective production of long-chain aldehydes, ketones or alcohols via syngas at a mild condition[J]. Applied Catalysis B: Environment and Energy, 2022, 307: 121155.
21	SHENG Yao, POLYNSKI Mikhail V, ESWARAN Mathan K, et al. A review of mechanistic insights into CO₂ reduction to higher alcohols for rational catalyst design[J]. Applied Catalysis B: Environmental, 2024, 343: 123550.
22	WANG Yanqiu, XU Di, ZHANG Xinxin, et al. Selective C₂₊ alcohol synthesis by CO₂ hydrogenation via a reaction-coupling strategy[J]. Catalysis Science & Technology, 2022, 12(5): 1539-1550.
23	WANG Yanqiu, ZHOU Ying, ZHANG Xinxin, et al. PdFe Alloy-Fe₅C₂ interfaces for efficient CO₂ hydrogenation to higher alcohols[J]. Applied Catalysis B: Environment and Energy, 2024, 345: 123691.
24	XU Jing, WEI Jian, ZHANG Jixin, et al. Precisely synergistic synthesis of higher alcohols from syngas over iron carbides[J]. Chem Catalysis, 2023, 3(4): 100584.
25	LI Linge, QING Ming, LIU Xingwu, et al. Efficient one-pot synthesis of higher alcohols from syngas catalyzed by iron nitrides[J]. ChemCatChem, 2020, 12(7): 1939-1943.
26	ZENG Zhuang, LI Zhuoshi, KANG Li, et al. A monodisperse ε′-(Co _x Fe_1- _x )_2.2C bimetallic carbide catalyst for direct conversion of syngas to higher alcohols[J]. ACS Catalysis, 2022, 12(10): 6016-6028.
27	ZENG Feng, MEBRAHTU Chalachew, XI Xiaoying, et al. Catalysts design for higher alcohols synthesis by CO₂ hydrogenation: Trends and future perspectives[J]. Applied Catalysis B: Environmental, 2021, 291: 120073.
28	王康明, 张海涛, 李涛. CuFe(100)及(110)面上合成气制低碳醇碳链增长机理研究[J]. 华东理工大学学报(自然科学版), 2022, 48(2): 139-147.
	WANG Kangming, ZHANG Haitao, LI Tao. Carbon chain growth mechanism of higher alcohols formation from syngas on CuFe(100) and(110)[J]. Journal of East China University of Science and Technology, 2022, 48(2): 139-147.
29	QIAN Weixin, WANG Hao, XU Yanbo, et al. In situ DRIFTS study of homologous reaction of methanol and higher alcohols synthesis over Mn promoted Cu-Fe catalysts[J]. Industrial & Engineering Chemistry Research, 2019, 58(16): 6288-6297.
30	LU Yongwu, CAO Baobao, YU Fei, et al. High selectivity higher alcohols synthesis from syngas over three-dimensionally ordered macroporous Cu-Fe catalysts[J]. ChemCatChem, 2014, 6(2): 473-478.
31	LU Yongwu, ZHANG Riguang, CAO Baobao, et al. Elucidating the copper-Hägg iron carbide synergistic interactions for selective CO hydrogenation to higher alcohols[J]. ACS Catalysis, 2017, 7(8): 5500-5512.
32	WANG Yang, WANG Kangzhou, ZHANG Baizhang, et al. Direct conversion of CO₂ to ethanol boosted by intimacy-sensitive multifunctional catalysts[J]. ACS Catalysis, 2021, 11(18): 11742-11753.
33	HE Yiming, MÜLLER Fabian H, PALKOVITS Regina, et al. Tandem catalysis for CO₂ conversion to higher alcohols: A review[J]. Applied Catalysis B: Environment and Energy, 2024, 345: 123663.
34	PRIETO Gonzalo. Carbon dioxide hydrogenation into higher hydrocarbons and oxygenates: Thermodynamic and kinetic bounds and progress with heterogeneous and homogeneous catalysis[J]. ChemSusChem, 2017, 10(6): 1056-1070.
35	XIAO Kang, BAO Zhenghong, QI Xingzhen, et al. Structural evolution of CuFe bimetallic nanoparticles for higher alcohol synthesis[J]. Journal of Molecular Catalysis A: Chemical, 2013, 378: 319-325.
36	XIAO Kang, QI Xingzhen, BAO Zhenghong, et al. CuFe, CuCo and CuNi nanoparticles as catalysts for higher alcohol synthesis from syngas: A comparative study[J]. Catalysis Science & Technology, 2013, 3(6): 1591-1602.
37	XIAO Kang, BAO Zhenghong, QI Xingzhen, et al. Unsupported CuFe bimetallic nanoparticles for higher alcohol synthesis via syngas[J]. Catalysis Communications, 2013, 40: 154-157.
38	HAN Xinyou, FANG Kegong, SUN Yuhan. Effects of metal promotion on CuMgFe catalysts derived from layered double hydroxides for higher alcohol synthesis via syngas[J]. RSC Advances, 2015, 5(64): 51868-51874.
39	HAN Xinyou, FANG Kegong, ZHOU Juan, et al. Synthesis of higher alcohols over highly dispersed Cu-Fe based catalysts derived from layered double hydroxides[J]. Journal of Colloid and Interface Science, 2016, 470: 162-171.
40	BAO Zhenghong, XIAO Kang, QI Xingzhen, et al. Higher alcohol synthesis over Cu-Fe composite oxides with high selectivity to C₂₊OH[J]. Journal of Energy Chemistry, 2013, 22(1): 107-113.
41	GUO Haijun, ZHANG Hairong, PENG Fen, et al. Effects of Cu/Fe ratio on structure and performance of attapulgite supported CuFeCo-based catalyst for mixed alcohols synthesis from syngas[J]. Applied Catalysis A: General, 2015, 503: 51-61.
42	BAI Nan, GAO Zhihua, HAO Chunyao, et al. Complete liquid-phase preparation of CuFe-based catalysts and their application in the synthesis of higher alcohols from syngas[J]. ChemistrySelect, 2020, 5(22): 6585-6593.
43	宁珣. Co基双金属催化剂催化合成气转化制备乙醇和高级醇[D]. 北京: 北京化工大学, 2016.
	NING Xun. Co-based bimetallic catalyst for synthesis of ethanol and higher alcohols from syngas[D]. Beijing: Beijing University of Chemical Technology, 2016.
44	ZHU Jie, MU Minchen, LIU Yi, et al. Unveiling the promoting effect of potassium on the structural evolution of iron catalysts during CO₂ hydrogenation[J]. Chemical Engineering Science, 2023, 282: 119228.
45	LIN Tiejun, QI Xingzhen, WANG Xinxing, et al. Direct production of higher oxygenates by syngas conversion over a multifunctional catalyst[J]. Angewandte Chemie International Edition, 2019, 58(14): 4627-4631.
46	XU Di, DING Mingyue, HONG Xinlin, et al. Mechanistic aspects of the role of K promotion on Cu-Fe-based catalysts for higher alcohol synthesis from CO₂ hydrogenation[J]. ACS Catalysis, 2020, 10(24): 14516-14526.
47	SI Zhiyan, AMOO Cederick Cyril, HAN Yu, et al. Sputtering FeCu nanoalloys as active sites for alkane formation in CO₂ hydrogenation[J]. Journal of Energy Chemistry, 2022, 70: 162-173.
48	DING Mingyue, TU Junling, QIU Minghuang, et al. Impact of potassium promoter on Cu-Fe based mixed alcohols synthesis catalyst[J]. Applied Energy, 2015, 138: 584-589.
49	DING Mingyue, MA Longlong, ZHANG Qian, et al. Enhancement of conversion from bio-syngas to higher alcohols fuels over K-promoted Cu-Fe bimodal pore catalysts[J]. Fuel Processing Technology, 2017, 159: 436-441.
50	HUANG Jiamin, ZHANG Guanghui, ZHU Jie, et al. Boosting the production of higher alcohols from CO₂ and H₂ over Mn- and K-modified iron carbide[J]. Industrial & Engineering Chemistry Research, 2022, 61(21): 7266-7274.
51	XI Xiaoying, ZENG Feng, ZHANG Heng, et al. CO₂ hydrogenation to higher alcohols over K-promoted bimetallic Fe-In catalysts on a Ce-ZrO₂ support[J]. ACS Sustainable Chemistry & Engineering, 2021, 9(18): 6235-6249.
52	GOUD Devender, CHURIPARD Sathyapal R, BAGCHI Debabrata, et al. Strain-enhanced phase transformation of iron oxide for higher alcohol production from CO₂ [J]. ACS Catalysis, 2022, 12(18): 11118-11128.
53	XU Di, DING Mingyue, HONG Xinlin, et al. Selective C₂₊ alcohol synthesis from direct CO₂ hydrogenation over a Cs-promoted Cu-Fe-Zn catalyst[J]. ACS Catalysis, 2020, 10(9): 5250-5260.
54	LIANG Jie, WANG Xinyu, GAO Xinhua, et al. Effect of Na promoter and reducing atmosphere on phase evolution of Fe-based catalyst and its CO₂ hydrogenation performance[J]. Journal of Fuel Chemistry and Technology, 2022, 50(12): 1573-1580.
55	ZENG Zhuang, LI Zhuoshi, GUAN Tong, et al. CoFe alloy carbide catalysts for higher alcohols synthesis from syngas: Evolution of active sites and Na promoting effect[J]. Journal of Catalysis, 2022, 405: 430-444.
56	YAO Ruwei, WEI Jian, GE Qingjie, et al. Monometallic iron catalysts with synergistic Na and S for higher alcohols synthesis via CO₂ hydrogenation[J]. Applied Catalysis B: Environmental, 2021, 298: 120556.
57	王昊, 钱炜鑫, 马宏方, 等. 不同Mn含量Cu-Fe基催化剂合成低碳醇的原位红外光谱及反应性能研究[J]. 天然气化工(C1化学与化工), 2018, 43(6): 34-38.
	WANG Hao, QIAN Weixin, MA Hongfang, et al. In situ DRFTIR and reaction performance investigation of Cu-Fe based catalysts with different content of Mn for higher alcohols synthesis[J]. Natural Gas Chemical Industry, 2018, 43(6): 34-38.
58	XU Yanbo, MA Hongfang, ZHANG Haitao, et al. Cu-promoted iron catalysts supported on nanorod-structured Mn-Ce mixed oxides for higher alcohol synthesis from syngas[J]. Catalysts, 2020, 10(10): 1124.
59	周瑶. Fe基多金属催化剂的制备及CO₂加氢制取低碳醇的性能研究[D]. 银川: 宁夏大学, 2023.
	ZHOU Yao. Preparation of Fe-based polymetallic catalysts and study on the performance of CO₂ hydrogenation to produce low carbon alcohols[D]. Yinchuan: Ningxia University, 2023.
60	GE Yuzhen, ZOU Tangsheng, MARTÍN Antonio J, et al. ZrO₂-promoted Cu-Co, Cu-Fe and Co-Fe catalysts for higher alcohol synthesis[J]. ACS Catalysis, 2023, 13(15): 9946-9959.
61	YANG Yanzhang, WANG Lei, XIAO Kang, et al. Elucidation of reaction network of higher alcohol synthesis over modified FT catalysts by probe molecule experiments[J]. Catalysis Science & Technology, 2015, 5(8): 4224-4232.
62	ZHANG Qian, WANG Sen, SHI Xuerong, et al. Conversion of CO₂ to higher alcohols on K-CuZnAl/Zr-CuFe composite[J]. Applied Catalysis B: Environment and Energy, 2024, 346: 123748.
63	LIAO Peiyi, ZHANG Chen, ZHANG Lijun, et al. Effect of promoter and CO₂ content in the feed on the performance of CuFeZr catalyst in the synthesis of higher alcohol from syngas[J]. Journal of Fuel Chemistry and Technology, 2017, 45(5): 547-555.
64	沈亚星. CuFe浆状催化剂低温合成低碳醇性能的研究[D]. 太原: 太原理工大学, 2022.
	SHEN Yaxing. Study on Cu Fe slurry catalyst performance for higher alcohol synthesis at low temperature[D]. Taiyuan: Taiyuan University of Technology, 2022.
65	李印文. CuFe基二元催化剂的制备及合成气转化制长链醇的性能研究[D]. 北京: 北京化工大学, 2019.
	LI Yinwen. Preparation of CuFe binary catalysts towards syngas conversion to long-chain alcohol[D]. Beijing: Beijing University of Chemical Technology, 2019.
66	ZENG Zhuang, LI Zhuoshi, GUO Shaoxia, et al. Janus Au-Fe_2.2C catalyst for direct conversion of syngas to higher alcohols[J]. ACS Sustainable Chemistry & Engineering, 2021, 9(33): 11258-11268.
67	夏万东, 高洪成. 镧改性Cu-Fe/SiO₂催化剂催化合成气制备低碳醇[J]. 精细化工, 2018, 35(4): 603-607.
	XIA Wandong, GAO Hongcheng. Synthesis of higher alcohols from syngas over lanthanum modified Cu-Fe/SiO₂ [J]. Fine Chemicals, 2018, 35(4): 603-607.
68	ZHANG Qian, WANG Sen, GENG Rui, et al. Hydrogenation of CO₂ to higher alcohols on an efficient Cr-modified CuFe catalyst[J]. Applied Catalysis B: Environmental, 2023, 337: 123013.
69	CAPARRÓS Francisco J, SOLER Lluís, ROSSELL Marta D, et al. Remarkable carbon dioxide hydrogenation to ethanol on a palladium/iron oxide single-atom catalyst[J]. ChemCatChem, 2018, 10(11): 2365-2369.
70	SHI Xinping, YU Haibing, GAO Shan, et al. Synergistic effect of nitrogen-doped carbon-nanotube-supported Cu-Fe catalyst for the synthesis of higher alcohols from syngas[J]. Fuel, 2017, 210: 241-248.
71	JIA Yazhen, WANG Bin, WEN Yueli, et al. Mechanism of stability and deactivation of N-doped CuFeZn catalysts for C₂₊ alcohols synthesis by hydrogenation of CO₂ [J]. Fuel Processing Technology, 2023, 250: 107901.
72	WANG Yanqiu, ZHANG Xinxin, HONG Xinlin, et al. Sulfate-promoted higher alcohol synthesis from CO₂ hydrogenation[J]. ACS Sustainable Chemistry & Engineering, 2022, 10(27): 8980-8987.
73	YANG Wanliang, CHEN Meng, ZHOU Jiayuan, et al. Preparation and evaluation of highly dispersed HHSS supported Cu-Fe bimetallic catalysts for higher alcohols synthesis from syngas[J]. Applied Catalysis A: General, 2020, 608: 117868.
74	DING Mingyue, TU Junlin, TSUBAKI Noritatsu, et al. Design of bimodal pore Cu-Fe based catalyst with enhanced performances for higher alcohols synthesis[J]. Energy Procedia, 2015, 75: 767-772.
75	GONG Nana, WU Yingquan, MA Qingxiang, et al. A simple strategy stabilizing for a CuFe/ SiO₂ catalyst and boosting higher alcohols’ synthesis from syngas[J]. Catalysts, 2023, 13(2): 237.
76	胡伟. 合成气制低碳醇Cu-Fe催化剂的制备及改性机制研究[D]. 上海: 华东理工大学, 2017.
	HU Wei. Preparation of Cu-Fe catalysts for low carbon alcohols and mechanism research[D]. Shanghai: East China University of Science and Technology, 2017.
77	黄乐. 合成气制高碳醇CuFe催化剂研究[D]. 上海: 华东理工大学, 2021.
	HUANG Le. Study on CuFe catalysts for higher alcohols synthesis from syngas[D]. Shanghai: East China University of Science and Technology, 2021.
78	GUO Haijun, ZHANG Hairong, PENG Fen, et al. Mixed alcohols synthesis from syngas over activated palygorskite supported Cu-Fe-Co based catalysts[J]. Applied Clay Science, 2015, 111: 83-89.
79	ZHANG J, LI Y. Higher alcohols from syngas with graphite oxide modified CuFeMn catalyst with low CO₂ selectivity[J]. Kinetics and Catalysis, 2020, 61(6): 861-868.
80	GAO Wa, ZHAO Yufei, CHEN Haoran, et al. Core-shell Cu@(CuCo-alloy)/Al₂O₃ catalysts for the synthesis of higher alcohols from syngas[J]. Green Chemistry, 2015, 17(3): 1525-1534.
81	DU Hong, ZHU Hejun, ZHAO Ziang, et al. Effects of impregnation strategy on structure and performance of bimetallic CoFe/AC catalysts for higher alcohols synthesis from syngas[J]. Applied Catalysis A: General, 2016, 523: 263-271.
82	王新略, 穆晓亮, 韩念琛, 等. 制备方法对CuFe负载介孔SiO₂催化剂合成气制低碳醇催化性能的影响[J]. 天然气化工—C1化学与化工, 2022, 47(4): 57-65.
	WANG Xinlue, MU Xiaoliang, HAN Nianchen, et al. Effect of preparation methods on catalytic performance of CuFe supported mesoporous SiO₂ catalyst for syngas to higher alcohols[J]. Natural Gas Chemical Industry, 2022, 47(4): 57-65.
83	SUN Chao, MAO Dongsen, HAN Lupeng, et al. Effect of impregnation sequence on performance of SiO₂ supported Cu-Fe catalysts for higher alcohols synthesis from syngas[J]. Catalysis Communications, 2016, 84: 175-178.
84	HE Shun, WANG Wei, SHEN Zheng, et al. Carbon nanotube-supported bimetallic Cu-Fe catalysts for syngas conversion to higher alcohols[J]. Molecular Catalysis, 2019, 479: 110610.
85	GUO Haijun, LI Qinglin, ZHANG Hairong, et al. Attapulgite supported Cu-Fe-Co based catalyst combination system for CO hydrogenation to lower alcohols[J]. Journal of Fuel Chemistry and Technology, 2019, 47(11): 1346-1356.
86	高娃. 铜基催化剂双活性位结构调控及其协同催化作用机制研究[D]. 北京: 北京化工大学, 2016.
	GAO Wa. Modulation of double active sites in Cu-based catalysts and corresponding cooperative catalysis mechanism[D]. Beijing: Beijing University of Chemical Technology, 2016.
87	LI Yinwen, GAO Wa, PENG Mi, et al. Interfacial Fe₅C₂-Cu catalysts toward low-pressure syngas conversion to long-chain alcohols[J]. Nature Communications, 2020, 11(1): 61.
88	HOU Bin, HAN Xinyou, LIN Minggui, et al. Preparation of SiO₂-coated CuFe catalysts for synthesis of higher alcohols from CO hydrogenation[J]. Journal of Fuel Chemistry and Technology, 2016, 44(2): 217-224.
89	CHEN Yanping, MA Lixuan, ZHANG Riguang, et al. Carbon-supported Fe catalysts with well-defined active sites for highly selective alcohol production from Fischer-Tropsch synthesis[J]. Applied Catalysis B: Environmental, 2022, 312: 121393.
90	XU Di, YANG Hengquan, HONG Xinlin, et al. Tandem catalysis of direct CO₂ hydrogenation to higher alcohols[J]. ACS Catalysis, 2021, 11(15): 8978-8984.
91	CAO Ang, YANG Qilei, WEI Ying, et al. Synthesis of higher alcohols from syngas over CuFeMg-LDHs/CFs composites[J]. International Journal of Hydrogen Energy, 2017, 42(27): 17425-17434.
92	HAN Tong, ZHAO Lin, LIU Guilong, et al. Rh-Fe alloy derived from YRh_0.5Fe_0.5O₃/ZrO₂ for higher alcohols synthesis from syngas[J]. Catalysis Today, 2017, 298: 69-76.
93	YANG Chen, WANG Bin, WEN Yueli, et al. Composition control of CuFeZn catalyst derived by PDA and its effect on synthesis of C₂₊ alcohols from CO₂ [J]. Fuel, 2022, 327: 125055.
94	KIM Tae-Wan, KLEITZ Freddy, Jong Won JUN, et al. Catalytic conversion of syngas to higher alcohols over mesoporous perovskite catalysts[J]. Journal of Industrial and Engineering Chemistry, 2017, 51: 196-205.
95	STEIN Andreas, LI Fan, DENNY Nicholas R. Morphological control in colloidal crystal templating of inverse opals, hierarchical structures, and shaped particles[J]. Chemistry of Materials, 2008, 20(3): 649-666.

催化剂	CO转化率/%	选择性/%			醇分布/%
催化剂	CO转化率/%	CO₂	HC	ROH	甲醇	C_2-5醇	C₆₊醇
CuFe	92.8	29.6	55.2	15.2	27.9	57.1	15.0
CuFe/SiO₂	84.8	22.0	58.2	19.8	26.2	57.4	16.4
CuFe/Al₂O₃	80.4	25.4	58.3	16.3	25.0	61.4	13.6
CuFe/CeO₂	85.8	28.6	56.1	15.3	33.5	54.7	11.8

催化剂	CO转化率/%	选择性/%			醇分布/%
催化剂	CO转化率/%	CO₂	HC	ROH	甲醇	C_2-5醇	C₆₊醇
CuFe	92.8	29.6	55.2	15.2	27.9	57.1	15.0
CuFe/SiO₂	84.8	22.0	58.2	19.8	26.2	57.4	16.4
CuFe/Al₂O₃	80.4	25.4	58.3	16.3	25.0	61.4	13.6
CuFe/CeO₂	85.8	28.6	56.1	15.3	33.5	54.7	11.8

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Advances in Fe-based catalysts for conversion of syngas/CO₂ to higher alcohols

合成气/CO₂转化制高级醇Fe基催化剂研究进展

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