Recent research and prospect of liquid organic hydrogen carries technology

doi:10.16085/j.issn.1000-6613.2023-0515

Abstract

Abstract:

As the vision of building a green hydrogen society, the demand for hydrogen energy will grow massively on a large scale as well, but the storage and transportation will also be the bottleneck that restricts the scale of the industrial development. Liquid organic hydrogen carries (LOHCs) have advantages over conventional high-pressure hydrogen storage methods in terms of low cost and safety for the large-scale storage and long-distance transportation of hydrogen energy. However, this technology is still at the early stage of development, and the related reports are limited. This paper reviews the main liquid organic hydrogen materials, aromatic such as aromatic hydrocarbons and aza-aromatic hydrocarbons, and analyses their hydrogen storage properties, advantages, problems and development status. Furthermore, various metal catalysts involved in hydrogenation and dehydrogenation processes are described. Finally, based on the current research, the prospects for liquid organic hydrogen storage technology are presented and the feasibility of liquid organic hydrogen storage technology in various fields and its high economic values are pointed out. However, for large-scale application, it's necessary to select the optimal liquid organic hydrogen materials, develop new catalysts with high selectivity, high catalytic activity and low cost, and further optimize hydrogenation and dehydrogenation technologies.

Key words: liquid organic hydrogen carriers, hydrogen storage material, aromatic hydrocarbons, aza-aromatic hydrocarbons, catalyst, hydrogenation, dehydrogenation, hydrogen

摘要：

随着构建绿色氢能社会愿景的提出，氢能的需求量将会大规模增长，氢能的储运就成为了制约产业规模化发展的瓶颈。液态有机储氢技术在氢能大规模储存和长距离运输上具有成本低、安全性高等传统高压储氢无法比拟的优势，由于这项技术目前仍处于发展初期，国内相关的报道较少。本文综述了芳香烃类和氮杂环芳香烃类等主要的液态有机储氢材料，并对其储氢性能、优势、存在问题及发展现状展开了分析；阐述了液态有机储氢技术中加氢和脱氢过程所涉及的各种金属催化剂的性能。基于目前的研究，对液态有机储氢技术在未来氢能规模化应用方面的发展前景进行了展望，同时指出液态有机储氢技术在诸多氢能应用领域的可行性及其极高的经济价值。但是若要实现大规模应用，则需选择更优的有机储氢材料，开发高选择性、高催化活性及低成本的新型催化剂，进一步优化加氢和脱氢技术。

关键词: 液态有机储氢, 储氢材料, 芳香烃类, 氮杂环芳香烃类, 催化剂, 加氢, 脱氢, 氢

CLC Number:

TK91

LIU Ruolu, TANG Haibo, HE Feifei, LUO Fengying, WANG Jinge, YANG Na, LI Hongwei, ZHANG Ruiming. Recent research and prospect of liquid organic hydrogen carries technology[J]. Chemical Industry and Engineering Progress, 2024, 43(4): 1731-1741.

刘若璐, 汤海波, 何翡翡, 罗凤盈, 王金鸽, 杨娜, 李洪伟, 张锐明. 液态有机储氢技术研究现状与展望[J]. 化工进展, 2024, 43(4): 1731-1741.

Figures/Tables 14

References 58

1	YASUSHI Sekine, TAKUMA Higo. Recent trends on the dehydrogenation catalysis of liquid organic hydrogen carrier (LOHC): A review[J]. Topics in Catalysis, 2021, 64(7): 470-480.
2	周一鸣, 齐随涛, 周宇亮, 等. 多环芳烃类液体有机氢载体储放氢技术研究进展[J]. 化工进展, 2023, 42(2): 1000-1007.
	ZHOU Yiming, QI Suitao, ZHOU Yuliang, et al. Research progress in the hydrogenation and dehydrogenation technology of polycyclic aromatic hydrocarbon liquid organic hydrogen carriers[J]. Chemical Industry and Engineering Progress, 2023, 42(2): 1000-1007.
3	张媛媛, 赵静, 鲁锡兰, 等. 有机液体储氢材料的研究进展[J]. 化工进展, 2016, 35(9): 2869-2874.
	ZHANG Yuanyuan, ZHAO Jing, LU Xilan, et al. Progress in liquid organic hydrogen storage materials[J]. Chemical Industry and Engineering Progress, 2016, 35(9): 2869-2874.
4	MODISHA Phillimon M, OUMA Cecil N M, GARIDZIRAI Rudaviro, et al. The prospect of hydrogen storage using liquid organic hydrogen carriers[J]. Energy & Fuels, 2019, 33(4): 2778-2796.
5	宋鹏飞, 侯建国, 王秀林. 甲基环己烷-甲苯液体有机物储氢技术的研究进展[J]. 天然气化工(C1化学与化工), 2021, 46(S1): 18-23.
	SONG Pengfei, HOU Jianguo, WANG Xiulin. Research progress on methylcyclohexane-toluene liquid organic hydrogen storage technology[J]. Natural Gas Chemical Industry, 2021, 46(S1): 18-23.
6	王蒙恩, 田亚飞, 张智芳, 等. 环己烷、甲基环己烷和乙基环己烷脱氢反应的热力学计算[J]. 石化技术与应用, 2022, 40(4): 238-242.
	WANG Meng’en, TIAN Yafei, ZHANG Zhifang, et al. Thermodynamic calculation of dehydrogenation of cyclohexane, methyl cyclohexane and ethyl cyclohexane[J]. Petrochemical Technology & Application, 2022, 40(4): 238-242.
7	Nicole BRÜCKNER, OBESSER Katharina, Andreas BÖSMANN, et al. Evaluation of industrially applied heat-transfer fluids as liquid organic hydrogen carrier systems[J]. ChemSusChem, 2014, 7(1): 229-235.
8	BOLLMANN Jonas, SCHMIDT Nikolas, BECK Dominik, et al. A path to a dynamic hydrogen storage system using a liquid organic hydrogen carrier (LOHC): Burner-based direct heating of the dehydrogenation unit[J]. International Journal of Hydrogen Energy, 2023, 48(3): 1011-1023.
9	DÜRR S, ZILM S, GEIßELBRECHT M, et al. Experimental determination of the hydrogenation/dehydrogenation-Equilibrium of the LOHC system H0/H18-dibenzyltoluene[J]. International Journal of Hydrogen Energy, 2021, 46(64): 32583-32594.
10	MA Jialing, YIN Lifei, LING Lixia, et al. The formation of high energy density fuel via the hydrogenation of naphthalene over Ni catalyst: The combined DFT and microkinetic analysis[J]. Fuel, 2023, 333: 126307.
11	ZHAO Tong, ZHAO Binbin, NIU Yufeng, et al. Hydrogenation of naphthalene to decalin catalyzed by Pt supported on WO₃ of different crystallinity at low temperature[J]. Journal of Fuel Chemistry and Technology, 2021, 49(8): 1181-1189.
12	SHIN Byeong Soo, YOON Chang Won, KWAK Sang Kyu, et al. Thermodynamic assessment of carbazole-based organic polycyclic compounds for hydrogen storage applications via a computational approach[J]. International Journal of Hydrogen Energy, 2018, 43(27): 12158-12167.
13	ZHU Qilong, XU Qiang. Liquid organic and inorganic chemical hydrides for high-capacity hydrogen storage[J]. Energy & Environmental Science, 2015, 8(2): 478-512.
14	EMEL’YANENKO Vladimir N, ZAITSAU Dzmitry H, PIMERZIN Andrey A, et al. N-phenyl-carbazole as a potential liquid organic hydrogen carrier: Thermochemical and computational study[J]. The Journal of Chemical Thermodynamics, 2019, 132: 122-128.
15	WU Yong, YU Hongen, GUO Yanru, et al. A rare earth hydride supported ruthenium catalyst for the hydrogenation of N-heterocycles: Boosting the activity via a new hydrogen transfer path and controlling the stereoselectivity[J]. Chemical Science, 2019, 10(45): 10459-10465.
16	STARK Katharina, KEIL Philipp, SCHUG Sebastian, et al. Melting points of potential liquid organic hydrogen carrier systems consisting of N-alkylcarbazoles[J]. Journal of Chemical & Engineering Data, 2016, 61(4): 1441-1448.
17	VOSTRIKOV Sergey V, KONNOVA Maria E, TUROVTZEV Vladimir V, et al. Thermodynamics of hydrogen storage: Equilibrium study of the LOHC system indole/octahydroindole[J]. Fuel, 2023, 335: 127025.
18	YANG Ming, CHENG Guoe, XIE Dandan, et al. Study of hydrogenation and dehydrogenation of 1-methylindole for reversible onboard hydrogen storage application[J]. International Journal of Hydrogen Energy, 2018, 43(18): 8868-8876.
19	LI Linlin, YANG Ming, DONG Yuan, et al. Hydrogen storage and release from a new promising liquid organic hydrogen storage carrier (LOHC): 2-methylindole[J]. International Journal of Hydrogen Energy, 2016, 41(36): 16129-16134.
20	DONG Yuan, YANG Ming, YANG Zihua, et al. Catalytic hydrogenation and dehydrogenation of N-ethylindole as a new heteroaromatic liquid organic hydrogen carrier[J]. International Journal of Hydrogen Energy, 2015, 40(34): 10918-10922.
21	DONG Yuan, YANG Ming, LI Linlin, et al. Study on reversible hydrogen uptake and release of 1,2-dimethylindole as a new liquid organic hydrogen carrier[J]. International Journal of Hydrogen Energy, 2019, 44(10): 4919-4929.
22	PREUSTER Patrick, PAPP Christian, WASSERSCHEID Peter. Liquid organic hydrogen carriers (LOHCs): Toward a hydrogen-free hydrogen economy[J]. Accounts of Chemical Research, 2017, 50(1): 74-85.
23	SAFRONOV Sergey P, VOSTRIKOV Sergey V, SAMAROV Artemiy A, et al. Comprehensive thermodynamic study of substituted indoles/perhydro indoles as potential liquid organic hydrogen carrier system[J]. Fuel, 2023, 331: 125764.
24	SCHWARZ Matthias, BACHMANN Philipp, SILVA Thais Nascimento, et al. Model catalytic studies of novel liquid organic hydrogen carriers: Indole, indoline and octahydroindole on Pt(111)[J]. Chemistry, 2017, 23(59): 14806-14818.
25	WEI Zhongzhe, SHAO Fangjun, WANG Jianguo. Recent advances in heterogeneous catalytic hydrogenation and dehydrogenation of N-heterocycles[J]. Chinese Journal of Catalysis, 2019, 40(7): 980-1002.
26	SAFRONOV Sergey P, VOSTRIKOV Sergey V, SAMAROV Artemiy A, et al. Reversible storage and release of hydrogen with LOHC: Evaluation of thermochemical data for methyl-quinolines with complementary experimental and computational methods[J]. Fuel, 2022, 317: 123501.
27	CHAUHAN Arzoo, KAR Ashish Kumar, SRIVASTAVA Rajendra. Ru-decorated N-doped carbon nanoflakes for selective hydrogenation of levulinic acid to γ-valerolactone and quinoline to tetrahydroquinoline with HCOOH in water[J]. Applied Catalysis A: General, 2022, 636: 118580.
28	SUN Feifei, AN Yue, LEI Lecheng, et al. Identification of the starting reaction position in the hydrogenation of (N-ethyl)carbazole over Raney-Ni[J]. Journal of Energy Chemistry, 2015, 24(2): 219-224.
29	JIANG Zhao, GUO Shuyi, FANG Tao. Enhancing the catalytic activity and selectivity of PdAu/SiO₂ bimetallic catalysts for dodecahydro-N-ethylcarbazole dehydrogenation by controlling the particle size and dispersion[J]. ACS Applied Energy Materials, 2019, 2(10): 7233-7243.
30	Francisco MARTINEZ-ESPINAR, BLONDEAU Pascal, NOLIS Pau, et al. NHC-stabilised Rh nanoparticles: Surface study and application in the catalytic hydrogenation of aromatic substrates[J]. Journal of Catalysis, 2017, 354: 113-127.
31	SHI Libin, ZHOU Yiming, QI Suitao, et al. Pt catalysts supported on H₂ and O₂ plasma-treated Al₂O₃ for hydrogenation and dehydrogenation of the liquid organic hydrogen carrier pair dibenzyltoluene and perhydrodibenzyltoluene[J]. ACS Catalysis, 2020, 10(18): 10661-10671.
32	WANG Shengdong, HUANG Haiyun, BRUNEAU Christian, et al. Iridium-catalyzed hydrogenation and dehydrogenation of N-heterocycles in water under mild conditions[J]. ChemSusChem, 2019, 12(11): 2350-2354.
33	明卫星, 李明璇, 纪璐, 等. 2-萘酚选择性加氢催化剂及工艺研究[J]. 染料与染色, 2022, 59(5): 44-46, 43.
	MING Weixing, LI Mingxuan, JI Lu, et al. Study on catalyst and process for selective hydrogenation of 2-naphthol[J]. Dyestuffs and Coloration, 2022, 59(5): 44-46, 43.
34	梁瑜, 赵彤, 赵斌彬, 等. WO₃对Pt/α-Al₂O₃催化萘深度加氢的促进作用[J]. 化工学报, 2021, 72(11): 5643-5652.
	LIANG Yu, ZHAO Tong, ZHAO Binbin, et al. Promotion of WO₃ species on Pt/α-Al₂O₃ for the deep hydrogenation of naphthalene[J]. CIESC Journal, 2021, 72(11): 5643-5652.
35	XUE Wenjie, LIU Hongxia, MAO Baohua, et al. Reversible hydrogenation and dehydrogenation of N-ethylcarbazole over bimetallic Pd-Rh catalyst for hydrogen storage[J]. Chemical Engineering Journal, 2021, 421: 127781.
36	ZHU Ting, YANG Ming, CHEN Xuedi, et al. A highly active bifunctional Ru-Pd catalyst for hydrogenation and dehydrogenation of liquid organic hydrogen carriers[J]. Journal of Catalysis, 2019, 378: 382-391.
37	DING Chenghan, ZHU Ting, WANG Fanyi, et al. High active Pd@MIL-101 catalyst for dehydrogenation of liquid organic hydrogen carrier[J]. International Journal of Hydrogen Energy, 2020, 45(32): 16144-16152.
38	袁胜楠, 张龙龙, 郭锦平, 等. 催化剂钯负载量对液态有机物脱氢性能的影响[J]. 当代化工研究, 2022(11): 27-29.
	YUAN Shengnan, ZHANG Longlong, GUO Jinping, et al. Effect of palladium loading of catalyst on dehydrogenation of liquid organic hydrogen carriers[J]. Modern Chemical Research, 2022(11): 27-29.
39	SHUANG Huili, CHEN Hao, WU Fei, et al. Catalytic dehydrogenation of hydrogen-rich liquid organic hydrogen carriers by palladium oxide supported on activated carbon[J]. Fuel, 2020, 275: 117896.
40	WANG Bin, CHANG Tieyan, JIANG Zhao, et al. Catalytic dehydrogenation study of dodecahydro-N-ethylcarbazole by noble metal supported on reduced graphene oxide[J]. International Journal of Hydrogen Energy, 2018, 43(15): 7317-7325.
41	FENG Zhaolu, BAI Xuefeng. Enhanced activity of bimetallic Pd-Ni nanoparticles on KIT-6 for production of hydrogen from dodecahydro-N-ethylcarbazole[J]. Fuel, 2022, 329: 125473.
42	LEE Sanghun, LEE Jaemyung, KIM Taehong, et al. Pt/CeO₂ catalyst synthesized by combustion method for dehydrogenation of perhydro-dibenzyltoluene as liquid organic hydrogen carrier: Effect of pore size and metal dispersion[J]. International Journal of Hydrogen Energy, 2021, 46(7): 5520-5529.
43	CHEN Xuedi, LI Gen, GAO Min, et al. Wet-impregnated bimetallic Pd-Ni catalysts with enhanced activity for dehydrogenation of perhydro-N-propylcarbazole[J]. International Journal of Hydrogen Energy, 2020, 45(56): 32168-32178.
44	龚翔, 李林森, 姜召. PdCo/SiO₂双金属催化剂用于杂环储氢载体的高效脱氢[J]. 化工学报, 2022, 73(10): 4448-4460.
	GONG Xiang, LI Linsen, JIANG Zhao. Employing PdCo/SiO₂ catalyst in high activity dehydrogenation reaction of heterocyclic H₂ storage carrier[J]. CIESC Journal, 2022, 73(10): 4448-4460.
45	VICERICH María A, BENITEZ Viviana M, SÁNCHEZ María A, et al. Ru-Pt catalysts supported on Al₂O₃ and SiO₂-Al₂O₃ for the selective ring opening of naphthenes[J]. The Canadian Journal of Chemical Engineering, 2020, 98(3): 749-756.
46	MIAO Lei, YAN Jing, WANG Weiyan, et al. Dehydrogenation of methylcyclohexane over Pt supported on Mg-Al mixed oxides catalyst: The effect of promoter Ir[J]. Chinese Journal of Chemical Engineering, 2020, 28(9): 2337-2342.
47	OUMA C N M, OBODO K O, MODISHA Phillimon M, et al. Effect of chalcogen (S, Se and Te) surface additives on the dehydrogenation of a liquid organic hydrogen carrier system, octahydroindole-indole, on a Pt (111) surface[J]. Applied Surface Science, 2021, 566: 150636.
48	CHEN Ben, HUI Bowen, DONG Yuting, et al. Distributions of Ni in MCM-41 for the hydrogenation of N-ethylcarbazole[J]. Fuel, 2022, 324: 124405.
49	DING Yuhang, DONG Yuan, ZHANG Heshun, et al. A highly adaptable Ni catalyst for Liquid Organic Hydrogen Carriers hydrogenation[J]. International Journal of Hydrogen Energy, 2021, 46(53): 27026-27036.
50	Ahsan ALI, Udaya KUMAR G, LEE Hee Joon. Investigation of hydrogenation of Dibenzyltoluene as liquid organic hydrogen carrier[J]. Materials Today: Proceedings, 2021, 45: 1123-1127.
51	冯小阳, 蒋利军, 李志念, 等. 富镍镧镍合金催化二苄基甲苯加氢性能研究[J]. 太阳能学报, 2022, 43(6): 382-388.
	FENG Xiaoyang, JIANG Lijun, LI Zhinian, et al. Hydrogenation performance of dibenzyltoluene catalyzed by Ni-rich La-Ni alloys[J]. Acta Energiae Solaris Sinica, 2022, 43(6): 382-388.
52	SU Xiaoping, AN Pu, GAO Junwen, et al. Selective catalytic hydrogenation of naphthalene to tetralin over a Ni-Mo/Al₂O₃ catalyst[J]. Chinese Journal of Chemical Engineering, 2020, 28(10): 2566-2576.
53	HERVOCHON Julien, DORCET Vincent, JUNGE Kathrin, et al. Convenient synthesis of cobalt nanoparticles for the hydrogenation of quinolines in water[J]. Catalysis Science & Technology, 2020, 10(14): 4820-4826.
54	WEI Zhongzhe, CHEN Yiqing, WANG Jing, et al. Cobalt encapsulated in N-doped graphene layers: An efficient and stable catalyst for hydrogenation of quinoline compounds[J]. ACS Catalysis, 2016, 6(9): 5816-5822.
55	HE Zhenhong, SUN Yongchang, WANG Kuan, et al. Reversible aerobic oxidative dehydrogenation/hydrogenation of N-heterocycles over AlN supported redox cobalt catalysts[J]. Molecular Catalysis, 2020, 496: 111192.
56	LEE Jusung, CHERIF Ali, YOON Hajun, et al. Large-scale overseas transportation of hydrogen: Comparative techno-economic and environmental investigation[J]. Renewable and Sustainable Energy Reviews, 2022, 165: 112556.
57	BULGARIN Alexander, JORSCHICK Holger, PREUSTER Patrick, et al. Purity of hydrogen released from the liquid organic hydrogen carrier compound perhydro dibenzyltoluene by catalytic dehydrogenation[J]. International Journal of Hydrogen Energy, 2020, 45(1): 712-720.
58	JORSCHICK Holger, VOGL Marius, PREUSTER Patrick, et al. Hydrogenation of liquid organic hydrogen carrier systems using multicomponent gas mixtures[J]. International Journal of Hydrogen Energy, 2019, 44(59): 31172-31182.

序号	名称	质量储氢密度/%	体积储氢密度/kg·m^-3	熔点/℃	沸点/℃	脱氢焓/kJ·mol^-1
1	咔唑	6.7	87	48.12	355	48.12
2	N-甲基咔唑	6.2	—	89	337.8	49.1
3	N-乙基咔唑	5.8	54.0	68	348	50.6
4	N-乙酰咔唑	6.32	63.83	77	315.5	—
5	N-苯甲酰咔唑	6.92	68.92	101	391.2	—
6	N-苯基咔唑	6.94	67.11	70	415.3	57.7

序号	名称	质量储氢密度/%	体积储氢密度/kg·m^-3	熔点/℃	沸点/℃	脱氢焓/kJ·mol^-1
1	咔唑	6.7	87	48.12	355	48.12
2	N-甲基咔唑	6.2	—	89	337.8	49.1
3	N-乙基咔唑	5.8	54.0	68	348	50.6
4	N-乙酰咔唑	6.32	63.83	77	315.5	—
5	N-苯甲酰咔唑	6.92	68.92	101	391.2	—
6	N-苯基咔唑	6.94	67.11	70	415.3	57.7

序号	名称	质量储氢密度/%	体积储氢密度/kg·m^-3	熔点/℃	沸点/℃	脱氢焓/kJ·mol^-1
1	吲哚	6.4	56	53	253	53.6
2	N-甲基吲哚	5.76	59.1	<-20	239	—
3	2-甲基吲哚	5.76	—	57	273	51.7
4	N-乙基吲哚	5.23	—	-17.8	253.5	—
5	1,2-二甲基吲哚	5.23	—	55	260.5	—

序号	名称	质量储氢密度/%	体积储氢密度/kg·m^-3	熔点/℃	沸点/℃	脱氢焓/kJ·mol^-1
1	吲哚	6.4	56	53	253	53.6
2	N-甲基吲哚	5.76	59.1	<-20	239	—
3	2-甲基吲哚	5.76	—	57	273	51.7
4	N-乙基吲哚	5.23	—	-17.8	253.5	—
5	1,2-二甲基吲哚	5.23	—	55	260.5	—

序号	催化剂	反应物	完全加氢产物	温度/℃	压力/MPa	时间/h	转换率/%	选择性/%	参考文献
1	5% Ru/Al₂O₃	1-甲基吲哚	8H-1-甲基吲哚	130	6	—	100	100	[18]
2	5% Ru/Al₂O₃	2-甲基吲哚	8H-2-甲基吲哚	170	7	0.5	>99	>99	[19]
3	5% Ru/Al₂O₃	1-乙基吲哚	8H-1-乙基吲哚	190	9	1.33	100	100	[20]
4	5% Ru/Al₂O₃	1-乙基吲哚	8H-1-乙基吲哚	160	9	4	100	100	[20]
5	4.6% Ru/Al₂O₃	N-乙基咔唑	12H-N-乙基咔唑	130	7	10	—	100	[15]
6	1.3% Ru/YH3	N-乙基咔唑	12H-N-乙基咔唑	130	7	10	—	100	[15]
7	1.3% Ru/YH3	2-甲基吲哚	8H-2-甲基吲哚	130	7	10	100	100	[15]
8	0.62% Ru^0.2	喹啉	十氢喹啉	60	2	24	100	—	[30]
9	3% Pt/ Al₂O₃-P-O₂	二苄基甲苯	18H-二苄基甲苯	140	4	0.5	>99	—	[31]
10	1% Pt/WO₃-500	萘	十氢化萘	70	3	1	100	100	[11]
11	2% Ir3	喹啉	1,2,3,4-四氢喹啉	80	0.1	17	99	98	[32]
12	Ru-Ni/C	2-萘酚	5,6,7,8-四氢-2-萘酚	90	4	3	100	71.08	[33]
13	1% Pt-WO₃/α-Al₂O₃	萘	十氢化萘	70	3	1	100	100	[34]
14	1% Pd-Rh/γ-Al₂O₃	N-乙基咔唑	12H-N-乙基咔唑	160	6	1	100	100	[35]
15	Ru-Pd/Al₂O₃	N-丙基咔唑	12H-N-丙基咔唑	150	7	7	>99	>99	[36]