Highly-efficient and autocatalytic reduction of NaHCO3 into formate by in situ hydrogen from water splitting with metal/metal oxide redox cycle

doi:10.1016/j.jechem.2017.08.011

能源化学(英文) ›› 2017, Vol. 26 ›› Issue (5): 881-890.DOI: 10.1016/j.jechem.2017.08.011

Highly-efficient and autocatalytic reduction of NaHCO₃ into formate by in situ hydrogen from water splitting with metal/metal oxide redox cycle

Guodong Yao^a, Jia Duo^a, Binbin Jin^a, Heng Zhong^b, Lingyun Lyu^a, Zhuang Ma^a, Fangming Jin^a,c

a School of Environmental Science and Engineering, State Key Lab of Metal Matrix Composites, Shanghai Jiao Tong University, 800 Dongchuan Road, Shanghai 200240, China;
b Research Institute for Chemical Process Technology, National Institute of Advanced Industrial Science and Technology(AIST), Nigatake 4-2-1, Miyagino-ku, Sendai 983-8551, Japan;
c Graduate School of Environmental Studies, Tohoku University, Aoba-ku, Sendai 980-8579, Japan

收稿日期:2017-07-16 修回日期:2017-08-22 出版日期:2017-09-15 发布日期:2017-11-10
通讯作者: Fangming Jin,E-mail address:fmjin@sjtu.edu.cn
作者简介:Fangming Jin received her Ph.D. from TohokuUniversity (Japan);Guodong Yao is currently a research associate at Shanghai Jiao Tong University;Heng Zhong received his Ph.D. in Chemistry from Tokyo University in 2015 and is currently a postdoctoral researcher in the National Institute of Advanced Industrial Science and Technology (AIST), Japan;Lingyun Lyu and Jia Duo received their Ph.D. from Shanghai Jiao Tong University in 2016 and 2017, respectively.
基金资助:
The authors gratefully acknowledge the financial support of the National Natural Science Foundation of China (Nos. 21277091 and 51472159), the State Key Program of National Natural Science Foundation of China (No. 21436007), the Key Basic Research Projects of Science and Technology Commission of Shanghai (No. 14JC1403100) and the Chenxing-SMG Young Scholar Project of Shanghai Jiao Tong University.

Highly-efficient and autocatalytic reduction of NaHCO₃ into formate by in situ hydrogen from water splitting with metal/metal oxide redox cycle

Guodong Yao^a, Jia Duo^a, Binbin Jin^a, Heng Zhong^b, Lingyun Lyu^a, Zhuang Ma^a, Fangming Jin^a,c

a School of Environmental Science and Engineering, State Key Lab of Metal Matrix Composites, Shanghai Jiao Tong University, 800 Dongchuan Road, Shanghai 200240, China;
b Research Institute for Chemical Process Technology, National Institute of Advanced Industrial Science and Technology(AIST), Nigatake 4-2-1, Miyagino-ku, Sendai 983-8551, Japan;
c Graduate School of Environmental Studies, Tohoku University, Aoba-ku, Sendai 980-8579, Japan

Received:2017-07-16 Revised:2017-08-22 Online:2017-09-15 Published:2017-11-10
Contact: Fangming Jin,E-mail address:fmjin@sjtu.edu.cn
Supported by:
The authors gratefully acknowledge the financial support of the National Natural Science Foundation of China (Nos. 21277091 and 51472159), the State Key Program of National Natural Science Foundation of China (No. 21436007), the Key Basic Research Projects of Science and Technology Commission of Shanghai (No. 14JC1403100) and the Chenxing-SMG Young Scholar Project of Shanghai Jiao Tong University.

摘要/Abstract

摘要： The Earth's sustainable development is threatened by the increasing atmospheric CO₂ level which can be attributed to the imbalance of CO₂ due to the rapid consumption of fossil fuels caused by human activities and the slow absorption and conversion of CO₂ by nature. One of the efficient methods for reconstructing the balance of CO₂ should involve the rapid conversion of CO₂ into fuels and chemicals. The hydrogenation of CO₂ with gaseous hydrogen is currently considered to be the most commercially feasible synthetic route, however, the supply of safe and economical hydrogen sources poses a significant challenge to up-scaling application. Direct utilization of hydrogen from dissociation of water, the most abundant, cheap and clean hydrogen resource, for the reduction of CO₂ would be one of the most promising approaches for CO₂ utilization. This paper provides an overview of the current advances in research on highly efficient reduction of CO₂ or NaHCO₃, a representative compound of CO₂, into formic acid/formate by in situ hydrogen from water dissociation with a metal/metal oxide redox cycle under mild hydrothermal conditions.

关键词: CO₂ reduction, Formate, Water splitting, Metal/metal oxide cycle, Hydrothermal conversion

Abstract: The Earth's sustainable development is threatened by the increasing atmospheric CO₂ level which can be attributed to the imbalance of CO₂ due to the rapid consumption of fossil fuels caused by human activities and the slow absorption and conversion of CO₂ by nature. One of the efficient methods for reconstructing the balance of CO₂ should involve the rapid conversion of CO₂ into fuels and chemicals. The hydrogenation of CO₂ with gaseous hydrogen is currently considered to be the most commercially feasible synthetic route, however, the supply of safe and economical hydrogen sources poses a significant challenge to up-scaling application. Direct utilization of hydrogen from dissociation of water, the most abundant, cheap and clean hydrogen resource, for the reduction of CO₂ would be one of the most promising approaches for CO₂ utilization. This paper provides an overview of the current advances in research on highly efficient reduction of CO₂ or NaHCO₃, a representative compound of CO₂, into formic acid/formate by in situ hydrogen from water dissociation with a metal/metal oxide redox cycle under mild hydrothermal conditions.

Key words: CO₂ reduction, Formate, Water splitting, Metal/metal oxide cycle, Hydrothermal conversion

Guodong Yao, Jia Duo, Binbin Jin, Heng Zhong, Lingyun Lyu, Zhuang Ma, Fangming Jin. Highly-efficient and autocatalytic reduction of NaHCO₃ into formate by in situ hydrogen from water splitting with metal/metal oxide redox cycle[J]. 能源化学(英文), 2017, 26(5): 881-890.

参考文献

[1] IPCC. Climate Change 2014:Synthesis Report. http://www.ipcc.ch/pdf/assessment-report/ar5/syr/SYR_AR5_FINAL_full_wcover.pdf,2015.

[2] CDIAC. Recent Greenhouse Gas Concentrations. http://cdiac.ornl.gov/pns/current_ghg.html,2017.

[3] K.S. Joya, Y.F. Joya, K. Ocakoglu, R. van de Krol, Angew. Chem. Int. Ed. 52(2013) 10426-10437.

[4] W. Kim, E. Edri, H. Frei, Acc. Chem. Res. 49(2016) 1634-1645.

[5] Q. Kong, D. Kim, C. Liu, Y. Yu, Y. Su, Y. Li, P. Yang, Nano Lett. 16(2016) 5675-5680.

[6] C. Liu, B.C. Colon, M. Ziesack, P.A. Silver, D.G. Nocera, Science 352(2016) 1210-1213.

[7] Y.S. Ham, S. Choe, M.J. Kim, T. Lim, S.K. Kim, J.J. Kim, Appl. Catal. B Environ. 208(2017) 35-43.

[8] C.D. Windle, R.N. Perutz, Coord. Chem. Rev. 256(2012) 2562-2570.

[9] K.P. Kuhl, E.R. Cave, D.N. Abram, T.F. Jaramillo, Energy Environ. Sci. 5(2012) 7050-7059.

[10] I. Ganesh, Renew. Sustain. Energy Rev. 59(2016) 1269-1297.

[11] A. Z'Graggen, A. Steinfeld, Int. J. Hydrogen Energy 33(2008) 5484-5492.

[12] A. Z'Graggen, A. Steinfeld, Chem. Eng. Proc. 47(2008) 655-662.

[13] L.O. Schunk, W. Lipinski, A. Steinfeld, Chem. Eng. J. 150(2009) 502-508.

[14] N. Piatkowski, C. Wieckert., A.W. Weimer, A. Steinfeld, Energy Environ. Sci. 4(2011) 73-82.

[15] W.C. Chueh, C. Falter, M. Abbott, D. Scipio, P. Furler, S.M. Haile, A. Steinfeld, Science 330(2010) 1797-1801.

[16] K. Rohmann, J. Kothe, M.W. Haenel, U. Englert, M. Hoelscher, W. Leitner, Angew. Chem. Int. Ed. 55(2016) 8966-8969.

[17] G. Bonura, F. Frusteri, C. Cannilla, G.D. Ferrante, A. Aloise, E. Catizzone, M. Migliori, G. Giordano, Catal. Today 277(2016) 48-54.

[18] P. Munshi, A.D. Main, J.C. Linehan, C.C. Tai, P.G. Jessop, J. Am. Chem. Soc. 124(2002) 7963-7971.

[19] X. Zhou, J. Qu, F. Xu, J. Hu, J.S. Foord, Z. Zeng, X. Hong, S.C.E. Tsang, Chem. Commun. 49(2013) 1747-1749.

[20] R. Tanaka, M. Yamashita, K. Nozaki, J. Am. Chem. Soc. 131(2009) 14168-14170.

[21] D.J. Frost, C.A. McCammon, Annu. Rev. Earth Planet. Sci. 36(2008) 389-420.

[22] D.J. Frost, C. Liebske, F. Langenhorst, C.A. McCammon, R.G. Tronnes, D.C. Rubie, Nature 428(2004) 409-412.

[23] C. McCammon, Science 308(2005) 807-808.

[24] W. Martin, J. Baross, D. Kelley, M.J. Russell, Nat. Rev. Microbiol. 6(2008) 805-814.

[25] G. Proskurowski, M.D. Lilley, J.S. Seewald, G.L. Fruh-Green, E.J. Olson, J.E. Lupton, S.P. Sylva, D.S. Kelley, Science 319(2008) 604-607.

[26] G. Proskurowski, M.D. Lilley, J.S. Seewald, G.L. Fruh-Green, E.J. Olson, J.E. Lupton, S.P. Sylva, D.S. Kelley, Geochim. Cosmochim. Acta 72(2008) A764.

[27] Q. Fu, B.S. Lollar, J. Horita, G. Lacrampe-Couloume, W.E. Seyfried Jr, Geochim. Cosmochim. Acta 71(2007) 1982-1998.

[28] F. Ji, H. Zhou, Q. Yang, Orig. Life Evol. Biosph. 38(2008) 117-125.

[29] D.I. Foustoukos, W.E. Seyfried, Science 304(2004) 1002-1005.

[30] H. Wang, Q. Yang, F. Ji, M.D. Lilley, H. Zhou, Mar. Chem. 134(2012) 29-35.

[31] Q. Fu, D.I. Foustoukos, W.E. Seyfried Jr, Geophys. Res. Lett. 35(2008) 7.

[32] N.G. Holm, J.L. Charlou, Earth Planet. Sci. Lett. 191(2011) 1-8.

[33] T.M. McCollom, J.S. Seewald, Geochim. Cosmochim. Acta 65(2001) 3769-3778.

[34] N. Yamasaki, J Ceram, Soc. Jpn. 111(2003) 709-715.

[35] G. Demazeau, Res. Chem. Intermed. 37(2011) 107-123.

[36] F.M. Jin, H. Enomoto, Energy Environ. Sci. 4(2011) 382-397.

[37] F. Jin, X. Zeng, J. Liu, Y. Jin, L. Wang, H. Zhong, G. Yao, Z. Huo, Sci. Rep. 4(2014) 1-8.

[38] F. Jin, X. Zeng, J. Yun, Z. Huo, Solar Chemical Energy Storage, 1568(Eds.), AIP Press, 2013, pp. 65-66.

[39] B. Wu, Y. Gao, F. Jin, J. Cao, Y. Du, Y. Zhang, Catal. Today 148(2009) 405-410.

[40] F. Jin, Abstr. Pap. Am. Chem. Soc. 242(2011) 1-2.

[41] F.M. Jin, Y. Gao, Y.J. Jin, Y.L. Zhang, J.L. Cao, Z. Wei, R.L. Smith, Energy Environ. Sci. 4(2011) 881-884.

[42] Z. Shen, Y.L. Zhang, F.M. Jin, Green Chem. 13(2011) 820-823.

[43] X. Zeng, F.M. Jin, Z.B. Huo, T. Mogi, A. Kishita, H. Enomoto, Energy Fuels 25(2011) 2749-2752.

[44] Z. Shen, Y. Zhang, F. Jin, RSC Adv. 2(2012) 797-801.

[45] L. Lyu, X. Zeng, J. Yun, F. Wei, F. Jin, Environ. Sci. Technol. 48(2014) 6003-6009.

[46] X. Zeng, M. Hatakeyama, K. Ogata, J. Liu, Y. Wang, Q. Gao, K. Fujii, M. Fujihira, F. Jin, S. Nakamura, Phys. Chem. Chem. Phys. 16(2014) 19836-19840.

[47] H. Zhong, Y. Gao, G. Yao, X. Zeng, Q. Li, Z. Huo, F. Jin, Chem. Eng. J. 280(2015) 215-221.

[48] J. Duo, F. Jin, Y. Wang, H. Zhong, L. Lyu, G. Yao, Z. Huo, Chem. Commun. 52(2016) 3316-3319.

[49] H. Zhong, H.S. Yao, J. Duo, G.D. Yao, F.M. Jin, Catal. Today 274(2016) 28-34.

[50] G.D. Yao, X. Zeng, Y.J. Jin, H. Zhong, J. Duo, F.M. Jin, Int. J. Hydrogen Energy 40(2015) 14284-14289.

[51] A. Boddien, F. Gaertner, C. Federsel, P. Sponholz, D. Mellmann, R. Jackstell, H. Junge, M. Beller, Angew. Chem. Int. Ed. 50(2011) 6411-6414.

[52] A. Boddien, D. Mellmann, F. Gaertner, R. Jackstell, H. Junge, P.J. Dyson, G. Laurenczy, R. Ludwig, M. Beller, Science 333(2011) 1733-1736.

[53] Q. Liu, X. Yang, Y. Huang, S. Xu, X. Su, X. Pan, J. Xu, A. Wang, C. Liang, X. Wang, T. Zhang, Energy Environ. Sci. 8(2015) 3204-3207.

[54] A. Boddien, C. Federsel, P. Sponholz, D. Mellmann, R. Jackstell, H. Junge, G. Laurenczy, M. Beller, Energy Environ. Sci. 5(2012) 8907-8911.

[55] M. Weber, J.T. Wang, S. Wasmus, R.F. Savinell, J. Electrochem. Soc. 143(1996) 158-160.

[56] N.V. Rees, R.G. Compton, J. Solid State Electrochem. 15(2011) 2095-2100.

[57] E.U. Franck, Fluid Phase Equilibria 10(1983) 211-222.

[58] Y. Yasaka, K. Yoshida, C. Wakai, N. Matubayasi, M. Nakahara, Phys. Chem. A 10(2006) 11082-11090.

[59] A.A. Peterson, F. Vogel, R.P. Lachance, M. Froeling, M.J. Antal Jr, J.W. Tester, Energy Environ. Sci. 1(2008) 32-65.

[60] F. Jin, J. Yun, G. Li, A. Kishita, K. Tohji, H. Enomoto, Green Chem. 10(2008) 612-615.

[61] C. Chauvin, J. Saussey, J.C. Lavalley, G. Djega-Mariadassou, Appl. Catal. 25(1986) 59-68.

[62] G.L. Griffin, J.T. Yates, J. Catal. 73(1982) 396-405.

[63] M. Grunze, W. Hirschwald, D. Hofmann, J. Cryst. Growth 52(1981) 241-249.

[64] P. Zapol, J.B. Jaffe, A.C. Hess, Surf. Sci. 422(1999) 1-7.

[65] W.S. Khan, C. Cao, G. Nabi, R. Yao, S.H. Bhatti, J. Alloys Compd. 506(2010) 666-672.

[66] D.M. Tang, G. Liu, F. Li, J. Tan, C. Liu, G.Q. Lu, H.M. Cheng, J. Phys. Chem. C 113(2009) 11035-11040.

[67] H.B. Zeng, P.S. Liu, W.P. Cai, X.L. Cao, S.K. Yang, Cryst. Growth Des. 7(2007) 1092-1097.

[68] Y. Le, H. Zhong, Y. Yang, R. He, G. Yao, F. Jin, J. Energy Chem. (2017), doi:10. 1016/j.jechem.2017.03.013.

[69] N.R. Neelameggham, J. Miner. Metals Mater. Soc. 61(2009) 25-27.

[70] S. Shabala, J. Miner. Metals Mater. Soc. 61(2009) 28-34.

Highly-efficient and autocatalytic reduction of NaHCO₃ into formate by in situ hydrogen from water splitting with metal/metal oxide redox cycle

Highly-efficient and autocatalytic reduction of NaHCO₃ into formate by in situ hydrogen from water splitting with metal/metal oxide redox cycle

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

[1]	Ziyue Zhou, Wenping Si, Pengyi Lu, Wenlei Guo, Lei Wang, Tao Zhang,feng Hou, Ji Liang. A flexible CNT@nickel silicate composite film for high-performance sodium storage[J]. 能源化学(英文版), 2020, 47(8): 29-37.
[2]	Yuxiao Ding, Qingqing Gu, Alexander Klyushin, Xing Huang, Sakeb H.Choudhury, Ioannis Spanos,feihong Song, Rik Mom, Pascal Düngen, Anna K.Mechler, Robert Schlögl, Saskia Heumann. Dynamic carbon surface chemistry: Revealing the role of carbon in electrolytic water oxidation[J]. 能源化学(英文版), 2020, 47(8): 155-159.
[3]	Meng Zha,chengang Pei, Quan Wang, Guangzhi Hu, Ligang Feng. Electrochemical oxygen evolution reaction efficiently boosted by selective fluoridation of FeNi₃ alloy/oxide hybrid[J]. 能源化学(英文版), 2020, 47(8): 166-171.
[4]	Puxuan Yan, Meilin Huang,benzhi Wang, Zixia Wan, Mancai Qian, Hu Yan, Tayirjan Taylor Isimjan, Jianniao Tian, Xiulin Yang. Oxygen defect-rich double-layer hierarchical porous Co₃O₄ arrays as high-efficient oxygen evolution catalyst for overall water splitting[J]. 能源化学(英文版), 2020, 47(8): 299-306.
[5]	Wei Liu, Hongxiu Zhang,chuanming Li, Xin Wang, Jingquan Liu, Xingwang Zhang. Non-noble metal single-atom catalysts prepared by wet chemical method and their applications in electrochemical water splitting[J]. 能源化学(英文版), 2020, 47(8): 333-345.
[6]	Xian Wang, Zelin Wang, Ya Bai, Ling Tan, Yanqi Xu, Xiaojie Hao, Jikang Wang, Abdul Hanif Mahadi, Yufei Zhao, Lirong Zheng, Yu-Fei Song. Tuning the selectivity of photoreduction of CO₂ to syngas over Pd/layered double hydroxide nanosheets under visible light up to 600 nm[J]. 能源化学(英文版), 2020, 46(7): 1-7.
[7]	Baoxin Wu, Hao Qian, Zhongwu Nie, Zhongping Luo, Zixu Wu, Peng Liu, Hao He, Jianghong Wu, Shuguang Chen, Feifei Zhang. Ni₃S₂ nanorods growing directly on Ni foam for allsolid-state asymmetric supercapacitor and efficient overall water splitting[J]. 能源化学(英文版), 2020, 46(7): 178-186.
[8]	Yanxia Ma, Miaomiao Wang, Xin Zhou. First-principles investigation of β-Ge₃N₄ loaded with RuO₂ cocatalyst for photocatalytic overall water splitting[J]. 能源化学(英文版), 2020, 44(5): 24-32.
[9]	Katarzyna Grubel, Hyangsoo Jeong, Chang Won Yoon, Tom Autrey. Challenges and opportunities for using formate to store, transport, and use hydrogen[J]. 能源化学(英文版), 2020, 41(2): 216-224.
[10]	Gui-Rong Zhang, Liu-Liu Shen, Patrick Schmatz, Konrad Krois, Bastian J.M.Etzold. Cathodic activated stainless steel mesh as a highly active electrocatalyst for the oxygen evolution reaction with self-healing possibility[J]. 能源化学(英文版), 2020, 49(10): 153-160.
[11]	Shen Zhang, Xing Zhang, Xuerong Shi, Feng Zhou, Ruihu Wang, Xiaoju Li. Facile fabrication of ultrafine nickel-iridium alloy nanoparticles/graphene hybrid with enhanced mass activity and stability for overall water splitting[J]. 能源化学(英文版), 2020, 49(10): 166-173.
[12]	Yilin Chen, Xingchen He, Dongsheng Guo, Yanqin Cai, Jingling Chen, Yun Zheng, Bifen Gao, Bizhou Lin. Supramolecular electrostatic self-assembly of mesoporous thin-walled graphitic carbon nitride microtubes for highly efficient visible-light photocatalytic activities[J]. 能源化学(英文版), 2020, 49(10): 214-223.
[13]	Tian-Feng Hou, Muhammad Ali Johar, Ramireddy Boppella, Mostafa Afifi Hassan, Swati J.Patil, Sang-Wan Ryu, Dong-Weon Lee. Vertically aligned one-dimensional ZnO/V₂O₅ core-shell hetero-nanostructure for photoelectrochemical water splitting[J]. 能源化学(英文版), 2020, 49(10): 262-274.
[14]	Jie Zhang, Sheng Fang, Xiaopeng Qi, Zhanglong Yu, Zhaohui Wu, Juanyu Yang, Shigang Lu. Preparation of high-purity straight silicon nanowires by molten salt electrolysis[J]. 能源化学(英文版), 2020, 40(1): 171-179.
[15]	Song Liu, Hongbin Yang, Xiong Su, Jie Ding, Qing Mao, Yanqiang Huang, Tao Zhang, Bin Liu. Rational design of carbon-based metal-free catalysts for electrochemical carbon dioxide reduction: A review[J]. 能源化学(英文版), 2019, 36(9): 95-105.