Perspective on the one-step CO2 hydrogenation to dimethyl ether

doi:10.16085/j.issn.1000-6613.2021-2239

Chemical Industry and Engineering Progress ›› 2022, Vol. 41 ›› Issue (3): 1115-1120.DOI: 10.16085/j.issn.1000-6613.2021-2239

• Perspective • Previous Articles Next Articles

Perspective on the one-step CO₂ hydrogenation to dimethyl ether

LIU Chang(), LIU Zhongwen()

Key Laboratory of Syngas Conversion of Shaanxi Province, School of Chemistry and Chemical Engineering, Shaanxi Normal University, Xi’an 710119, Shaanxi, China

Received:2021-11-01 Revised:2021-11-26 Online:2022-03-28 Published:2022-03-23
Contact: LIU Zhongwen

CO₂加氢一步制二甲醚展望

刘畅(), 刘忠文()

陕西师范大学化学化工学院，陕西省合成气转化重点实验室，陕西西安 710119

通讯作者: 刘忠文
作者简介:刘畅（1987—），男，副研究员，研究方向为CO2加氢与合成气转化。E-mail：chang_liu@snnu.edu.cn。
基金资助:
国家自然科学基金(21636006);中央高校优秀成果培育计划(GK201901001);陕西省自然科学基础研究计划青年项目(2021JQ-306)

Abstract

Abstract:

The hydrogenation of CO₂ to dimethyl ether (DME) is a potential method for the efficient utilization of CO₂ as a renewable resource. In comparison with the photocatalytic and electrocatalytic routes, the thermal conversion of CO₂ over a solid catalyst exhibits a higher efficiency. However, the reported catalysts for the one-step hydrogenation of CO₂ to DME commonly suffer from a lower activity and a poorer stability. In this perspective, progresses on the structure of active sites and the reaction mechanism of the one-step hydrogenation of CO₂ to DME are summarized for the Cu-based bifunctional catalyst and the recently reported GaN catalyst. In the case of the Cu-based bifunctional catalyst, DME is formed via the CO₂ hydrogenation to methanol and the dehydration of the intermediate methanol to DME. Moreover, copper at reduced state (Cu⁰, Cu⁺ or Cu ^δ⁺, 0<δ<2) is the active site for the CO₂ hydrogenation, and the DME yield and the stability of the bifunctional catalyst are mainly determined by the dispersion and the stability of reduced Cu, the strength and distribution of acid sites, and the synergetic effect between reduced Cu and the acid sites. In contrast, the GaN catalyzed DME synthesis proceeds via the direct hydrogenation of CO₂ to the primary product of DME, which is totally different from that over the Cu-based bifunctional catalysts. Based on these analyses, the challenges and the further researches on the one-step hydrogenation of CO₂ to DME are provided, and the benefit of the DME economy is remarked.

Key words: CO₂ hydrogenation, dimethyl ether, gallium nitride, copper, bifunctional catalyst

摘要：

CO₂加氢制二甲醚（DME）是有潜力实现CO₂资源化利用的重要途径之一。与光、电催化相比，CO₂的非均相催化转化具有转化效率高等优点，但目前CO₂加氢一步制备DME催化剂的反应活性较低、稳定性较差。本文在简要介绍CO₂加氢一步制DME的铜基双功能催化剂、复合氧化物和氮化镓催化剂的基础上，重点总结了活性中心结构和反应机理的研究进展。对于铜基双功能催化剂，CO₂加氢经甲醇中间体合成DME，其中还原态铜（Cu⁰、Cu⁺及Cu ^δ⁺，0<δ<2）是其催化活性中心，且还原态铜的分散度及稳定性、固体酸的性质和酸性位分布以及两类活性中心的耦合效应是决定DME收率和催化剂稳定性的关键因素。与此相反，DME是氮化镓催化CO₂加氢的初级产物。这与铜基双功能催化剂有着本质区别，属新催化剂体系。在此基础上，文章对CO₂加氢制DME的可能研究方向进行了展望，认为“二甲醚经济”更具发展潜力。

关键词: 二氧化碳加氢, 二甲醚, 氮化镓, 铜, 双功能催化剂

CLC Number:

O643.32

LIU Chang, LIU Zhongwen. Perspective on the one-step CO₂ hydrogenation to dimethyl ether[J]. Chemical Industry and Engineering Progress, 2022, 41(3): 1115-1120.

刘畅, 刘忠文. CO₂加氢一步制二甲醚展望[J]. 化工进展, 2022, 41(3): 1115-1120.

Figures/Tables 2

References 10

1	常雁红, 韩怡卓, 王心葵. 二甲醚的生产、应用及下游产品的开发[J]. 天然气化工, 2000, 25(3): 45-54.
	CHANG Yanhong, HAN Yizhuo, WANG Xinkui. Production, application and production, application and development of downstream products for dimethyl ether[J]. Natural Gas Chemical Industry, 2000, 25(3): 45-54.
2	秦祖赠, 刘瑞雯, 纪红兵, 等. 二氧化碳的活化及其催化加氢制二甲醚的研究进展[J]. 化工进展, 2015, 34(1): 119-126.
	QIN Zuzeng, LIU Ruiwen, JI Hongbing, et al. Recent advances in the activation of carbon dioxide and the synthesis of dimethyl ether by the catalytic hydrogenation of carbon dioxide[J]. Chemical Industry and Engineering Progress, 2015, 34(1): 119-126.
3	LIU C, KANG J, HUANG Z, et al. Gallium-nitride-catalyzed direct hydrogenation of carbon dioxide to dimethyl ether as primary product[J]. Nature Communications, 2021, 12: 2305.
4	MONDAL U, YADAV G. Perspective of dimethyl ether as fuel: Part I. Catalysis[J]. Journal of CO₂ Utilization, 2019, 32: 299-320.
5	徐敏杰, 朱明辉, 陈天元, 等. CO₂高值化利用：CO₂加氢制甲醇催化剂研究进展[J]. 化工进展, 2021, 40(2): 565-576.
	XU Minjie, ZHU Minghui, CHEN Tianyuan, et al. High value utilization of CO₂: research progress of catalyst for hydrogenation of CO₂ to methanol[J]. Chemical Industry and Engineering Progress, 2021, 40(2): 565-576.
6	BANSODE A, URAKAWA A. Towards full one-pass conversion of carbon dioxide to methanol and methanol-derived products[J]. Journal of Catalysis, 2014, 309: 66-70.
7	CHINCHEN G, DENNY P, PARKE D, et al. Mechanism of methanol synthesis from CO₂/CO/H₂mixtures over copper/zinc oxide/alumina catalysts: use of 14C-labelled reactants[J]. Applied Catalysis, 1987, 30(2): 333-338.
8	MORADI G, YARIPOUR F, VALE-SHEYDA P. Catalytic dehydration of methanol to dimethyl ether over mordenite catalysts[J]. Fuel Processing Technology, 2010, 91: 461-468.
9	LIU R, TIAN H, YANG A, et al. Preparation of HZSM-5 membrane packed CuO-ZnO-Al₂O₃ nanoparticles for catalysing carbon dioxide hydrogenation to dimethyl ether[J]. Applied Surface Science, 2015, 345: 1-9.
10	NI Y, CHEN Z, FU Y, et al. Selective conversion of CO₂ and H₂ into aromatics[J]. Nature Communications, 2018, 9: 3457.

[1]	ZHANG Jie, BAI Zhongbo, FENG Baoxin, PENG Xiaolin, REN Weiwei, ZHANG Jingli, LIU Eryong. Effect of PEG and its compound additives on post-treatment of electrolytic copper foils [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 374-381.
[2]	SHI Yongxing, LIN Gang, SUN Xiaohang, JIANG Weigeng, QIAO Dawei, YAN Binhang. Research progress on active sites in Cu-based catalysts for CO₂ hydrogenation to methanol [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 287-298.
[3]	WANG Yaogang, HAN Zishan, GAO Jiachen, WANG Xinyu, LI Siqi, YANG Quanhong, WENG Zhe. Strategies for regulating product selectivity of copper-based catalysts in electrochemical CO₂ reduction [J]. Chemical Industry and Engineering Progress, 2023, 42(8): 4043-4057.
[4]	WU Zhongjie, XIE Lianke, WANG Jinghui, HUANG Renliang. Preparation of hierarchical copper hydroxyl nitrate nanozyme for degradation of phenolic pollutants [J]. Chemical Industry and Engineering Progress, 2023, 42(1): 497-505.
[5]	SHI Xuan, YANG Dongyuan, HU Haobin, WANG Jiaofei, ZHANG Zhuangzhuang, HE Jianxun, DAI Chengyi, MA Xiaoxun. One-step preparation of toluene/xylene from benzene and syngas over ZnAlCrO _x &HZSM-5 bifunctional catalyst [J]. Chemical Industry and Engineering Progress, 2022, 41(S1): 247-259.
[6]	LI Qi, CHENG Zefang, BAI Miao, HU Pengfei. Melting characteristics of high porosity copper foam reinforced phase change materials [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 4928-4936.
[7]	HU Wende, WANG Yangdong, WANG Chuanming. Research progress on the direct catalytic conversion of syngas to light olefins [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 4754-4766.
[8]	ZHANG Peng, MENG Fanhui, YANG Guinan, LI Zhong. Progress of metal oxide in OX-ZEO catalyst for CO _x hydrogenation to light olefins [J]. Chemical Industry and Engineering Progress, 2022, 41(8): 4159-4172.
[9]	ZHU Mengshuai, WANG Zilong, SUN Xiangxin, ZHOU Xiang. Experimental research on effect of copper metal foam proportion on paraffin wax melting and heat transfer mechanism under high cell density [J]. Chemical Industry and Engineering Progress, 2022, 41(6): 3203-3211.
[10]	CHEN Bo, HONG Qiqi, TANG Lirong, ZHANG Weichuan, CHEN Weixiang, LI Xing, LYU Rixin, HUANG Biao. Humidity sensitive properties of lead-free copper-based perovskite Cs₂CuBr₄ [J]. Chemical Industry and Engineering Progress, 2022, 41(6): 3162-3169.
[11]	YANG Tao, WANG Xiaosheng, LI Ranjia, YU Changchun. Advances in the modification of mordenite catalysts for the carbonylation of dimethyl ether [J]. Chemical Industry and Engineering Progress, 2022, 41(5): 2451-2459.
[12]	WAN Qian, WANG Mingjie, HE Luxi, FENG Xiaojiang, HE Zhengbin, YI Songlin. Heat storage and release process and numerical simulation of copper foam/paraffin composite phase change material [J]. Chemical Industry and Engineering Progress, 2022, 41(4): 2046-2053.
[13]	LEI Qian, LIANG Linlin, LYU Gaomeng, CHEN Honglin. Synthesis of polyoxymethylene dimethyl ethers with shaped ZSM-5 catalysts in a fixed-bed reactor [J]. Chemical Industry and Engineering Progress, 2022, 41(4): 1908-1915.
[14]	HONG Qian, BAI Rui, PENG Xinhua, SUN Ming, LIU Shanshan, JIAO Linyu, MA Xiaoxun. Studies on the catalytic performance of supported copper in the α-nitration of naphthalene [J]. Chemical Industry and Engineering Progress, 2022, 41(4): 1894-1899.
[15]	WANG Jijie, HAN Zhe, CHEN Siyu, TANG Chizhou, SHA Feng, TANG Shan, YAO Tingting, LI Can. Liquid sunshine methanol [J]. Chemical Industry and Engineering Progress, 2022, 41(3): 1309-1317.