Photochemical hydrogen production with molecular devices comprising a zinc porphyrin and a cobaloxime catalyst

Science China Chemistry

Volumn 55, Issue 7, 2012, Pages 1274-1282

  Zhang, Pan ^a   Wang, Mei ^a   Li, Xue Qiang ^a   Cui, Hong Guang ^b   Dong, Jing Feng ^a   Sun, Li Cheng ^a,c  

^a DALIAN UNIVERSITY OF TECHNOLOGY   (China)

^b DALIAN UNIVERSITY   (China)

^c ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

Author keywords

Cobaloxime; Hydrogen production; Molecular device; Photocatalysis; Zinc porphyrin

Indexed keywords

AXIAL COORDINATION; CATALYST UNITS; COBALOXIMES; FLUORESCENCE QUENCHING; HYDROGEN GENERATIONS; INTRA-MOLECULAR ELECTRON TRANSFER; MOLECULAR DEVICE; MULTICOMPONENTS; PLAUSIBLE MECHANISMS; PYRIDYL; PYRIDYL GROUPS; SACRIFICIAL ELECTRON DONORS; SINGLET EXCITED STATE; TRIETHYLAMINES; TURNOVER NUMBER; VISIBLE LIGHT; ZINC PORPHYRINS; ZINC-PORPHYRIN;

CATALYSTS; CHROMOPHORES; COBALT; FLUORESCENCE; HYDROGEN PRODUCTION; NUCLEAR PHYSICS; PHOTOCATALYSIS; PHOTOSENSITIZERS; PORPHYRINS; PRECIOUS METALS; QUENCHING; ZINC;

ZINC COMPOUNDS;

EID: 84866069331     PISSN: 16747291     EISSN: None     Source Type: Journal    
DOI: 10.1007/s11426-012-4514-0     Document Type: Article

References (37)

1. Graetzel M. Artificial photosynthesis: Water cleavage into hydrogen and oxygen by visible light. Acc Chem Res, 1981, 14: 376-384
2. Service RF. Is it time to shoot for the sun? Science, 2005, 309: 548-551
3. Armaroli N, Balzani V. The future of energy supply: Challenges and opportunities. Angew Chem Int Ed, 2007, 46: 52-66
4. Abe R. Recent progress on photocatalytic and photoelectrochemical water splitting under visible light irradiation. J Photochem Photobio C, 2010, 4: 179-209
5. Esswein J, Nocera DG. Hydrogen production by molecular photocatalysis. Chem Rev, 2007, 107: 4022-4047
6. Bard AJ, Fox MA. Artificial photosynthesis:solar splitting of water to hydrogen and oxygen. Acc Chem Res, 1995, 28: 141-145
7. Losse S, Vos JG, Rau S. Catalytic hydrogen production at cobalt centres. Coord Chem Rev, 2010, 254: 2492-2504
8. Wang M, Na Y, Gorlov M, Sun L. Light-driven hydrogen production catalysed by transition metal complexes in homogeneous systems. Dalton Trans, 2009, 6458-6467
9. Ozawa H, Haga M, Sakai K. A photo-hydrogen-evolving molecular device driving visible-light-induced EDTA-reduction of water into molecular hydrogen. J Am Chem Soc, 2006, 128: 4926-4927
10. Rau S, Schaefer B, Gleich D, Anders E, Rudolph M, Friedrich M, Goerls H, Henry W, Vos JG. A supramolecular photocatalyst for the production of hydrogen and the selective hydrogenation of tolane. Angew Chem Int Ed, 2006, 45: 6215-6217
11. Wang WG, Wang F, Wang HY, Si G, Tung CH, Wu LZ. Photocatalytic hydrogen evolution by [FeFe] mimics in homogeneous solution. Chem Asian J, 2010, 5: 1796-1803
12. Elvington M, Brown J, Arachchige SM, Brewer KJ. Photocatalytic hydrogen production from water employing a Ru, Rh, Ru molecular device for photoinitiated electron collection. J Am Chem Soc, 2008, 129: 10644-10645
13. Fihri A, Artero V, Razavet M, Baffert C, Leibl W, Fontecave M. Cobaloxime-based photocatalytic devices for hydrogen production. Angew Chem Int Ed, 2008, 47: 564-567
14. Fihri A, Artero V, Pereira A, Fontecave M. Efficient H2-producing photocatalytic systems based on cyclometalated iridium and tricarbonylrhenium- dimine photosensitizers and cobaloxime catalysts. Dalton Trans, 2008, 5567-5569
15. Arachchige S, Brown J, Brewer K. Photochemical hydrogen production from water using the new photocatalyst[{(bpy)2Ru (dpp)}2RhBr2](PF6)5. J Photochem Photobio A, 2008, 197: 13-17
16. Sakai K, Ozawa H. Homogeneous catalysis of platinum (II) complexes in photochemical hydrogen production from water. Coord Chem Rev, 2007, 251: 2753-2766
17. Sun L, Åkermark B, Ott S. Iron hydrogenase active site mimics in supramolecular systems aiming for light driven hydrogen production. Coord Chem Rev, 2005, 249: 1653-1663
18. Li X, Wang M, Zhang S, Pan J, Na Y, Liu J, Åkermark B, Sun L. Noncovalent assembly of a metalloporphyrin and an iron hydrogenase active-site model: Photo-induced electron transfer and hydrogen generation. J Phys Chem B, 2008, 112: 8198-8202
19. 2S]-hydrogenase-based photocatalyst for molecular hydrogen evolution. Proc Natl Acad Sci, 2009, 106: 10460-10465
20. Song LC, Wang LX, Tang MY, Li CG, Song HB, Hu QM. Synthesis, structure, and photoinduced catalysis of [FeFe]-hydrogenase active site models covalently linked to a porphyrin or metalloporphyrin moiety. Organometallics, 2009, 28: 3834-3841
21. Zhang P, Wang M, Li C, Li X, Dong J, Sun L. Photochemical H2 production with noble-metal-free molecular devices comprising a porphyrin photosensitizer and a cobaloxime catalyst. Chem Comm, 2010, 46: 8806-8808.
22. Trogler W, Stewart R, Epps L, Marzilli L. Cis and trans effects on the proton magnetic resonance spectra of cobaloximes. Inorg Chem, 1974, 13: 1564-1570.
23. Schrauzer GN. Bis(dimethylglyoximato) cobalt complexes ("cobaloximes"). Inorg Synth, 1968, 11: 61-70
24. Fleischer EB, Shachter AM. Coordination oligomers and a coordination polymer of zinc tertraarylporphyrins. Inorg Chem, 1991, 30: 3763-3769
25. Aspley CJ, Smith JRL, Perutz RN, Pursche D. Synthesis and photochemistry of free base and zinc tetraaryl porphyrins mono-substituted with tungsten pentacarbonyl via a pyridine linker. Dalton Trans, 2002, 170-180
26. Leland BA, Joran AD, Felker PM, Hopfield JJ, Zewail AH, Dervan PB. Picosecond fluorescene studies on intramolecular photochemical electron transfer in porphyrins linked to quinones at two different fixed distances. J Phys Chem, 1985, 89: 5571-5573
27. -, and SCN-) on nanocrystaline titanium dioxide electrodes. J Am Chem Soc, 1993, 115: 6382-6390
28. Kavarnos GJ, Turro NJ. Photosensitization by reversible electron transfer: Theories, experimental evidence and examples. Chem Rev, 1986, 86: 401-449
29. Joran AD, Leland BA, Felker PM, Zewail AH, Hopfield JJ, Dervan PB. Effect of exothermicity on electron transfer rates in photosynthetic molecular models. Nature, 1987, 327: 508-511
30. Joran AD, Leland BA, Geller GG, Hopfield JJ, Dervan PB. Models for photochemical electron transfer at fixed distances. Porphyrin- bicyclo[2,2,2]octane-quinone and porphyrin-bisbicyclo[2,2,2] octane-quinone. J Am Chem Soc, 1984, 106: 6090-6092
31. Gabrielsson A, Smith JRL, Perutz RN. Remote site photosubstitution in metallpporphyrin-rhenium tricarbonylbipyridine assemblies: photo- reactions of molecules with very short lived excited states. Dalton Trans, 2008, 4259-4269
32. Razavet M, Artero V, Fontecave M. Proton electroreduction catalyzed by cobaloximes: functional models for hydrogenases. Inorg Chem, 2005, 44: 4786-4795
33. Du P, Schneider J, Luo G, Brennessel W, Eisenberg R. Visible light-driven hydrogen production from aqueous protons catalyzed by molecular cobaloxime catalysts. Inorg Chem, 2009, 48: 4952-4962
34. Dempsey JL, Brunschwig BS, Winkler JR, Gray HB. Hydrogen evolution catalyzed by cobaloximes. Acc Chem Res, 2009, 42: 1995-2004
35. Dempsey JL, Winkler JR, Gray HB. Kinetics of electron transfer reactions of H2-evolving cobalt diglyoxime catalysts. J Am Chem Soc, 2010, 132: 1060-1065
36. Hawecher J, Lehn JM, Ziessel R. Efficient homogeneous photochemical hydrogen genetation and water reduction mediated by cobaloxime or macrocyclic cobalt complexes. Nouv J Chim, 1983, 7: 271-277
37. DeLaive PJ, Foreman TK, Giannotti C, Whitten DG. Photoinduced electron transfer reactions of transition-metal complexes with amines. Mechanistic studies of alternate pathways to back electron transfer. J Am Chem SOC, 1980, 102: 5627-5631