Bio-inspired tetracarbene compounds as a new family of energy saving catalysts

doi:10.1016/j.jechem.2023.01.019

Journal of Energy Chemistry ›› 2023, Vol. 79 ›› Issue (4): 559-561.DOI: 10.1016/j.jechem.2023.01.019

Previous Articles Next Articles

Bio-inspired tetracarbene compounds as a new family of energy saving catalysts

Bo Zhang^a,b,*, Fritz E. Kühn^c,*

^aCAS Key Laboratory of Science and Technology on Applied Catalysis, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, Liaoning, China;
^bUniversity of Chinese Academy of Science, Beijing 100049, China;
^cMolecular Catalysis, Catalysis Research Center and Department of Chemistry, School of Natural Sciences, Technical University of Munich, Lichtenbergstr 4, 85748 Garching bei München, Germany

Received:2022-12-11 Revised:2022-12-28 Accepted:2023-01-10 Online:2023-04-15 Published:2023-05-30
Contact: * E-mail addresses: bo.zhang@dicp.ac.cn (B. Zhang), fritz.kuehn@ch.tum.de (F.E. Kühn).

Abstract

Bo Zhang, Fritz E. Kühn. Bio-inspired tetracarbene compounds as a new family of energy saving catalysts[J]. Journal of Energy Chemistry, 2023, 79(4): 559-561.

×
share this article

Add to citation manager EndNote|Ris|BibTeX

URL: https://www.jenergychem.com/EN/10.1016/j.jechem.2023.01.019

https://www.jenergychem.com/EN/Y2023/V79/I4/559

[1] H. Fischer, Die Naturwissenschaften 18(1930) 1026-1037.
[2] A. Treibs, J. Liebig Ann.Chem. 476(1929) 1-60.
[3] A.J. Arduengo, R.L. Harlow, M. Kline, J. Am. Chem.Soc. 113(1991) 361-363.
[4] A.J. Arduengo, H.V.R.Dias, R.L. Harlow, M. Kline, J.Am. Chem. Soc. 114(1992) 5530-5534.
[5] A. Igau, A. Baceiredo, G. Trinquier, G. Bertrand, Angew. Chem. Int. Ed. 28(1989) 621-622.
[6] W.A.Öfele K., Herrmann, D. Mihalios, M.Elison, E. Herdtweck, W. Scherer, Mink J., J. Organomet. Chem. 459(1993) 177-184.
[7] W.A. Herrmann, Angew. Chem. Int. Ed. 41(2002) 1290-1309.
[8] M.N. Hopkinson, C. Richter, M. Schedler, F. Glorius, Nature 510(2014) 485-496.
[9] P. de Fremont, N.Marion, S.P. Nolan, Coord. Chem. Rev. 253(2009) 862-892.
[10] J.A. Mata, M. Poyatos, E. Peris, Coord. Chem. Rev. 251(2007) 841-859.
[11] M. Poyatos, J.A. Mata, E. Peris, Chem. Rev. 109(2009) 3677-3707.
[12] P.G. Edwards, E.E. Hahn, Dalton Trans. 40(2011) 10278-10288.
[13] V. Charra, P. de Fremont, P.Braunstein, Coord. Chem. Rev. 341(2017) 53-176.
[14] J. Cheng, L. Wang, P. Wang, L. Deng, Chem. Rev. 118(2018) 9930-9987.
[15] F.E. Hahn, V. Langenhahn, T. Lügger, T. Pape, D. leVan, Angew.Chem. Int. Ed. 44(2005) 3759-3763.
[16] H.M. Bass, S.A. Cramer, J.L. Price, D.M. Jenkins, Organometallics 29(2010) 3235-3238.
[17] M.R. Anneser, S. Haslinger, A. Pöthig, M. Cokoja, J.M. Basset, F.E. Kühn, Inorg. Chem. 54(2015) 3797-3804.
[18] D.T. Weiß, S. Haslinger, C. Jandl, A. Pöthig, M. Cokoja, F.E. Kühn, Inorg. Chem. 54(2015) 415-417.
[19] L. Zheng, S.A. Cramer, D.M. Jenkins, Chem. Sci. 3(2012) 3081-3087.
[20] G.G. Zámbó, J.F. Schlagintweit, R.M. Reich, F.E. Kühn, Catal. Sci. Technol. 12(2022) 4940-4961.
[21] M.R. Anneser, G.R. Elpitiya, X.B. Powers, D.M. Jenkins, Organometallics 38(2019) 981-987.
[22] Y. Liu, S.G. Resch, I. Klawitter, G.E. Cutsail, S. Demeshko, S. Dechert, F.E. Kühn, S. DeBeer, F. Meyer, Angew. Chem. Int. Ed. 59(2020) 5696-5705.
[23] H.M. Bass, S.A. Cramer, A.S. McCullough, K.J. Bernstein, C.R. Murdock, D.M. Jenkins, Organometallics 32(2013) 2160-2167.
[24] G.G. Zámbó, J. Mayr, M.J. Sauer, T.P. Schlachta, R.M. Reich, F.E. Kühn, Dalton Trans. 51(2022) 13591-13595.
[25] F.E. Hahn, V. Langenhahn, T. Lügger, T. Pape, D.L. Van, Angew. Chem. Int. Ed. 44(2005) 3759-3763.
[26] R. McKie, J.A. Murphy, S.R. Park, M.D. Spicer, S. Zhou, Angew. Chem. Int. Ed. 46(2007) 6525-6528.
[27] A.H. Mageed, J. Organomet. Chem. 902(2019) 120965-120988.
[28] J.A. Jasniewski, L. Jr Que, Chem. Rev. 118(2018) 2554-2592.
[29] S.M. Hölzl, P.J. Altmann, J.W. Kück, F.E. Kühn, Coord. Chem. Rev. 352(2017) 517-536.
[30] P. Hu, M. Tan, L. Cheng, H. Zhao, R. Feng, W. Gu, W. Han, Nature Commun. 10(2019) 2425-2434.
[31] S. Shaik, K.D. Dubey, Trends Chem. 3(2021) 1027-1044.
[32] K. Riener, S. Haslinger, A. Raba, M.P. Högerl, M. Cokoja, W.A. Herrmann, F.E. Kühn, Chem. Rev. 114(2014) 5215-5272.
[33] Ö. Karaca, M.R. Anneser, J.W. Kück, A. Lindhorst, M. Cokoja, F.E. Kühn, J. Catal. 344(2016) 213-220.
[34] N.J. Findlay, S.R. Park, F. Schoenebeck, E. Cahard, S. Zhou, L.E.A.Berlouis, M.D. Spicer, T. Tuttle, J.A. Murphy, J. Am. Chem. Soc. 132(2010) 15462-15464.
[35] S.R. Park, N.J. Findlay, J. Garnier, S. Zhou, M.D. Spicer, J.A. Murphy, Tetrahedron 65(2009) 10756-10761.
[36] S.A. Cramer, D.M. Jenkins, J. Am. Chem.Soc. 133(2011) 19342-19345.
[37] J.F. Schlagintweit, P.J. Altmann, B.J. Hofmann, A.D. Böth, C. Jandl, C. Kaußler, L. Nguyen, R.M. Reich, A. Pöthig, F.E. Kühn, Chem. Eur. J. 18(2021) 1311-1315.
[38] W.R. Browne, B.L. Feringa, Nature Nanotech. 1(2006) 25-35.

Bio-inspired tetracarbene compounds as a new family of energy saving catalysts

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

[1]	Jinho Ahn, Hyunyoung Park, Wonseok Ko, Yongseok Lee, Jungmin Kang, Seokjin Lee, Sangyeop Lee, Eunji Sim, Kyuwook Ihm, Jihyun Hong, Jung-Keun Yoo, Kyojin Ku, Jongsoon Kim. Occurrence of anionic redox with absence of full oxidation to Ru⁵⁺ in high-energy P2-type layered oxide cathode [J]. Journal of Energy Chemistry, 2023, 84(9): 153-161.
[2]	Hua-Qing Yin, Zuo-Shu Sun, Qiu-Ping Zhao, Lu-Lu Yang, Tong-Bu Lu, Zhi-Ming Zhang. Electrochemical urea synthesis by co-reduction of CO₂ and nitrate with Fe^II-Fe^IIIOOH@BiVO₄ heterostructures [J]. Journal of Energy Chemistry, 2023, 84(9): 385-393.
[3]	Wa Gao, Yinwen Li, Dequan Xiao, Ding Ma. Advances in photothermal conversion of carbon dioxide to solar fuels [J]. Journal of Energy Chemistry, 2023, 83(8): 62-78.
[4]	Kai S. Exner. Standard-state entropies and their impact on the potential-dependent apparent activation energy in electrocatalysis [J]. Journal of Energy Chemistry, 2023, 83(8): 247-254.
[5]	Jing Zhang, Jia-Jun Dai, De-Quan Cao, Heng Xu, Xing-Yu Ding, Chun-Hua Zhen, Beate Paulus, Jin-Yu Ye, Qian Liang, Jun-Ke Liu, Shi-Jun Xie, Sai-Sai Deng, Zhen Wang, Jun-Tao Li, Yao Zhou, Shi-Gang Sun. Activating coordinative conjugated polymer via interfacial electron transfer for efficient CO₂ electroreduction [J]. Journal of Energy Chemistry, 2023, 83(8): 313-323.
[6]	Shengli Pang, Yifan Song, Meng Cui, Xin Tang, Chao Long, Lingfeng Ke, Gongmei Yang, Ting Fang, Yong Guan, Chonglin Chen. Rapid and durable oxygen reduction reaction enabled by a perovskite oxide with self-cleaning surface [J]. Journal of Energy Chemistry, 2023, 83(8): 333-340.
[7]	Chunhua Wang, Hongwen Zhang, Feili Lai, Zhirun Xie, Yun Hau Ng, Bo Weng, Xuejiao Wu, Yuhe Liao. Engineering versatile Au-based catalysts for solar-to-fuel conversion [J]. Journal of Energy Chemistry, 2023, 83(8): 341-362.
[8]	Limin Zhou, Yanyan Liu, Shuling Liu, Huanhuan Zhang, Xianli Wu, Ruofan Shen, Tao Liu, Jie Gao, Kang Sun, Baojun Li, Jianchun Jiang. For more and purer hydrogen-the progress and challenges in water gas shift reaction [J]. Journal of Energy Chemistry, 2023, 83(8): 363-396.
[9]	Medhanie Gebremedhin Gebru, Radhey Shyam Yadav, Hanan Teller, Haya Kornweitz, Palaniappan Subramanian, Alex Schechter. Harnessing dimethyl ether and methyl formate fuels for direct electrochemical energy conversion [J]. Journal of Energy Chemistry, 2023, 83(8): 454-464.
[10]	Yifei Li, Xilin Yuan, Ping Wang, Lulin Tang, Miao He, Pangen Li, Jiang Li, Zhenxing Li. Rare earth alloy nanomaterials in electrocatalysis [J]. Journal of Energy Chemistry, 2023, 83(8): 574-594.
[11]	Ruihui Gan, Yali Wang, Xiangwu Zhang, Yan Song, Jingli Shi, Chang Ma. Edge atomic Fe sites decorated porous graphitic carbon as an efficient bifunctional oxygen catalyst for Zinc-air batteries [J]. Journal of Energy Chemistry, 2023, 83(8): 602-611.
[12]	Haiwen Wei, Zhen Li, Honglei Wang, Yang Yang, Pengfei Cheng, Peigeng Han, Ruiling Zhang, Feng Liu, Panwang Zhou, Keli Han. Regulation of excitation energy transfer in Sb-alloyed Cs₄MnBi₂Cl₁₂ perovskites for efficient CO₂ photoreduction to CO and water oxidation toward H₂O₂ [J]. Journal of Energy Chemistry, 2023, 82(7): 18-24.
[13]	Guoqing Li, Xiaolong Zhao, Qihong Yue, Ping Fu, Fangpei Ma, Jun Wang, Yu Zhou. Reducing dielectric confinement effect in ionic covalent organic nanosheets to promote the visible-light-driven hydrogen evolution [J]. Journal of Energy Chemistry, 2023, 82(7): 40-46.
[14]	Xue-Ting Fan, Xiao-Jian Wen, Yong-Bin Zhuang, Jun Cheng. Molecular insight into the GaP(110)-water interface using machine learning accelerated molecular dynamics [J]. Journal of Energy Chemistry, 2023, 82(7): 239-247.
[15]	Di Liu, Zhejiaji Zhu, Jiani Li, Li-Wei Chen, Hui-Zi Huang, Xiao-Ting Jing, An-Xiang Yin. Rh-Cu alloy nano-dendrites with enhanced electrocatalytic ethanol oxidation activity [J]. Journal of Energy Chemistry, 2023, 82(7): 343-349.