Category:Homogeneous electrochemical CO2 conversion

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Literature

[DCC16] A Dinuclear Cobalt Cryptate as a Homogeneous Photocatalyst for Highly Selective and Efficient Visible‐Light Driven CO ₂ Reduction to CO in CH ₃ CN/H ₂ O Solution. Ting Ouyang, Hai‐Hua Huang, Jia‐Wei Wang, Di‐Chang Zhong, Tong‐Bu Lu, Angewandte Chemie 2016, Vol. 129, Pages 756-761. DOI2: 10.1002/ange.201610607
Publication: A Dinuclear Cobalt Cryptate as a Homogeneous Photocatalyst for Highly Selective and Efficient Visible-Light Driven CO2 Reduction to CO in CH3CN-H2O Solution

[AiR19] An integrated Re(i) photocatalyst/sensitizer that activates the formation of formic acid from reduction of CO₂. Yasmeen Hameed, Patrick Berro, Bulat Gabidullin, Darrin Richeson, Chemical Communications 2019, Vol. 55, Pages 11041-11044. DOI2: 10.1039/c9cc03943k
Publication: An integrated Re(I) photocatalyst and sensitizer that activates the formation of formic acid from reduction of CO2

[DSP19] Durable Solar-Powered Systems with Ni-Catalysts for Conversion of CO₂ or CO to CH₄. Hunter Shirley, Xiaojun Su, Harshin Sanjanwala, Kallol Talukdar, Jonah W. Jurss, Jared H. Delcamp, Journal of the American Chemical Society 2019, Vol. 141, Pages 6617-6622. DOI2: 10.1021/jacs.9b00937
Publication: Durable Solar-Powered Systems with Ni-Catalysts for Conversion of CO2 or CO to CH4

[ECD22] Exchange Coupling Determines Metal-Dependent Efficiency for Iron- and Cobalt-Catalyzed Photochemical CO₂ Reduction. Patricia De La Torre, Jeffrey S. Derrick, Andrew Snider, Peter T. Smith, Matthias Loipersberger, Martin Head-Gordon, Christopher J. Chang, ACS Catalysis 2022, Vol. 12, Pages 8484-8493. DOI2: 10.1021/acscatal.2c02072
Publication: Exchange Coupling Determines Metal-Dependent Efficiency for Iron- and Cobalt-Catalyzed Photochemical CO2 Reduction

[EtF21] Exploring the Full Potential of Photocatalytic Carbon Dioxide Reduction Using a Dinuclear Re ₂ Cl ₂ Complex Assisted by Various Photosensitizers. Robin Giereth, Martin Obermeier, Lukas Forschner, Michael Karnahl, Matthias Schwalbe, Stefanie Tschierlei, ChemPhotoChem 2021, Vol. 5, Pages 644-653. DOI2: 10.1002/cptc.202100034
Publication: Exploring the Full Potential of Photocatalytic Carbon Dioxide Reduction Using a Dinuclear Re2Cl2 Complex Assisted by Various Photosensitizers

[FIR18] Function-Integrated Ru Catalyst for Photochemical CO₂ Reduction. Sze Koon Lee, Mio Kondo, Masaya Okamura, Takafumi Enomoto, Go Nakamura, Shigeyuki Masaoka, Journal of the American Chemical Society 2018, Vol. 140, Pages 16899-16903. DOI2: 10.1021/jacs.8b09933
Publication: Function-Integrated Ru Catalyst for Photochemical CO2 Reduction

[HEa18] Highly Efficient and Robust Photocatalytic Systems for CO₂ Reduction Consisting of a Cu(I) Photosensitizer and Mn(I) Catalysts. Hiroyuki Takeda, Hiroko Kamiyama, Kouhei Okamoto, Mina Irimajiri, Toshihide Mizutani, Kazuhide Koike, Akiko Sekine, Osamu Ishitani, Journal of the American Chemical Society 2018, Vol. 140, Pages 17241-17254. DOI2: 10.1021/jacs.8b10619
Publication: Highly Efficient and Robust Photocatalytic Systems for CO2 Reduction Consisting of a Cu(I) Photosensitizer and Mn(I) Catalysts

[HEa16] Highly Efficient and Selective Photocatalytic CO₂ Reduction by Iron and Cobalt Quaterpyridine Complexes. Zhenguo Guo, Siwei Cheng, Claudio Cometto, Elodie Anxolabéhère-Mallart, Siu-Mui Ng, Chi-Chiu Ko, Guijian Liu, Lingjing Chen, Marc Robert, Tai-Chu Lau, Journal of the American Chemical Society 2016, Vol. 138, Pages 9413-9416. DOI2: 10.1021/jacs.6b06002
Publication: Highly Efficient and Selective Photocatalytic CO2 Reduction by Iron and Cobalt Quaterpyridine Complexes

[Hea18] Highly efficient and selective visible-light driven CO₂-to-CO conversion by a Co-based cryptate in H₂O/CH₃CN solution. Dong-Cheng Liu, Hong-Juan Wang, Jia-Wei Wang, Di-Chang Zhong, Long Jiang, Tong-Bu Lu, Chemical Communications 2018, Vol. 54, Pages 11308-11311. DOI2: 10.1039/c8cc04892d
Publication: Highly efficient and selective visible-light driven CO2-to-CO conversion by a Co-based cryptate in H2O-CH3CN solution

[Itb17] [Ir(tpy)(bpy)Cl] as a Photocatalyst for CO₂ Reduction under Visible-Light Irradiation. Shunsuke Sato, Takeshi Morikawa, ChemPhotoChem 2017, Vol. 2, Pages 207-212. DOI2: 10.1002/cptc.201700133
Publication: Ir(tpy)(bpy)Cl as a Photocatalyst for CO2 Reduction under Visible-Light Irradiation

[Mao20] Merging an organic TADF photosensitizer and a simple terpyridine–Fe(iii) complex for photocatalytic CO₂ reduction. Yanan Wang, Xue-Wang Gao, Junli Li, Duobin Chao, Chemical Communications 2020, Vol. 56, Pages 12170-12173. DOI2: 10.1039/d0cc05047d
Publication: Merging an organic TADF photosensitizer and a simple terpyridine–Fe(iii) complex for photocatalytic CO2 reduction

[Mcm17] Mn-carbonyl molecular catalysts containing a redox-active phenanthroline-5,6-dione for selective electro- and photoreduction of CO2 to CO or HCOOH. Matthew Stanbury, Jean-Daniel Compain, Monica Trejo, Parker Smith, Eric Gouré, Sylvie Chardon-Noblat, Electrochimica Acta 2017, Vol. 240, Pages 288-299. DOI2: 10.1016/j.electacta.2017.04.080
Publication: Mn-carbonyl molecular catalysts containing a redox-active phenanthroline-5,6-dione for selective electro- and photoreduction of CO2 to CO or HCOOH

[MCo15] Molecular Catalysis of the Electrochemical and Photochemical Reduction of CO₂ with Earth-Abundant Metal Complexes. Selective Production of CO vs HCOOH by Switching of the Metal Center. Lingjing Chen, Zhenguo Guo, Xi-Guang Wei, Charlotte Gallenkamp, Julien Bonin, Elodie Anxolabéhère-Mallart, Kai-Chung Lau, Tai-Chu Lau, Marc Robert, Journal of the American Chemical Society 2015, Vol. 137, Pages 10918-10921. DOI2: 10.1021/jacs.5b06535
Publication: Molecular Catalysis of the Electrochemical and Photochemical Reduction of CO2 with Earth-Abundant Metal Complexes. Selective Production of CO vs HCOOH by Switching of the Metal Center

[Nip18] Nickel(ii) pincer complexes demonstrate that the remote substituent controls catalytic carbon dioxide reduction. Dalton B. Burks, Shakeyia Davis, Robert W. Lamb, Xuan Liu, Roberta R. Rodrigues, Nalaka P. Liyanage, Yujie Sun, Charles Edwin Webster, Jared H. Delcamp, Elizabeth T. Papish, Chemical Communications 2018, Vol. 54, Pages 3819-3822. DOI2: 10.1039/c7cc09507d
Publication: Nickel(II) pincer complexes demonstrate that the remote substituent controls catalytic carbon dioxide reduction

[PSC22] Phenoxazine‐Sensitized CO ₂ ‐to‐CO Reduction with an Iron Porphyrin Catalyst: A Redox Properties‐Catalytic Performance Study. Martin Kientz, Grace Lowe, Blaine G. McCarthy, Garret M. Miyake, Julien Bonin, Marc Robert, ChemPhotoChem 2022, Vol. 6. DOI2: 10.1002/cptc.202200009
Publication: Phenoxazine-Sensitized CO2-to-CO Reduction with an Iron Porphyrin Catalyst: A Redox Properties-Catalytic Performance Study

[PCR20] Photocatalytic CO₂ Reduction Using a Robust Multifunctional Iridium Complex toward the Selective Formation of Formic Acid. Kenji Kamada, Jieun Jung, Taku Wakabayashi, Keita Sekizawa, Shunsuke Sato, Takeshi Morikawa, Shunichi Fukuzumi, Susumu Saito, Journal of the American Chemical Society 2020, Vol. 142, Pages 10261-10266. DOI2: 10.1021/jacs.0c03097
Publication: Photocatalytic CO2 Reduction Using a Robust Multifunctional Iridium Complex toward the Selective Formation of Formic Acid

[PCR20] Photocatalytic CO ₂ Reduction under Visible‐Light Irradiation by Ruthenium CNC Pincer Complexes. Yasuhiro Arikawa, Itoe Tabata, Yukari Miura, Hiroki Tajiri, Yudai Seto, Shinnosuke Horiuchi, Eri Sakuda, Keisuke Umakoshi, Chemistry – A European Journal 2020, Vol. 26, Pages 5603-5606. DOI2: 10.1002/chem.201905840
Publication: Photocatalytic CO2 Reduction under Visible-Light Irradiation by Ruthenium CNC Pincer Complexes

[PCr14] Photocatalytic CO₂reduction using a Mn complex as a catalyst. Hiroyuki Takeda, Hiroki Koizumi, Kouhei Okamoto, Osamu Ishitani, Chem. Commun. 2014, Vol. 50, Pages 1491-1493. DOI2: 10.1039/c3cc48122k
Publication: Photocatalytic CO2 reduction using a Mn complex as a catalyst

[PCr23] Photocatalytic CO2 reduction with aminoanthraquinone organic dyes. Qinqin Lei, Huiqing Yuan, Jiehao Du, Mei Ming, Shuang Yang, Ya Chen, Jingxiang Lei, Zhiji Han, Nature Communications 2023, Vol. 14. DOI2: 10.1038/s41467-023-36784-7
Publication: Photocatalytic CO2 reduction with aminoanthraquinone organic dyes

[PRo22] Photocatalytic Reduction of CO₂by Highly Efficient Homogeneous Fe^IICatalyst based on 2,6‐Bis(1’,2’,3’‐triazolyl‐methyl)pyridine. Comparison with Analogues.. Lisa‐Lou Gracia, Elham Barani, Jonas Braun, Anthony B. Carter, Olaf Fuhr, Annie K. Powell, Karin Fink, Claudia Bizzarri, ChemCatChem 2022, Vol. 14. DOI2: 10.1002/cctc.202201163
Publication: Photocatalytic Reduction of CO2 by Highly Efficient Homogeneous FeII Catalyst based on 2,6-Bis(1’,2’,3’-triazolyl-methyl)pyridine. Comparison with Analogues.

[PRo16] Photocatalytic Reduction of Carbon Dioxide to CO and HCO₂H Using fac-Mn(CN)(bpy)(CO)₃. Po Ling Cheung, Charles W. Machan, Aramice Y. S. Malkhasian, Jay Agarwal, Clifford P. Kubiak, Inorganic Chemistry 2016, Vol. 55, Pages 3192-3198. DOI2: 10.1021/acs.inorgchem.6b00379
Publication: Photocatalytic Reduction of Carbon Dioxide to CO and HCO2H Using fac-Mn(CN)(bpy)(CO)3

	cat	cat conc [µM]	PS	PS conc [mM]	e-D	e-D conc [M]	solvent A	additives	TON CO	TON CH4	TON H2	TON HCOOH	lit
1.	Molecule:100776	2.5E-5	[Ru(phen)3][PF6]2	0.4	TEOA	300	MeCN		16896		368		[DCC16]
2.	Molecule:100776	2.5E-5			TEOA	300	MeCN						[DCC16]
3.			[Ru(phen)3][PF6]2	0.4	TEOA	300	MeCN						[DCC16]
4.	Molecule:100776	2.5E-5	[Ru(phen)3][PF6]2	0.4	TEOA	300	MeCN						[DCC16]
5.	Molecule:100776	2.5E-5	[Ru(phen)3][PF6]2	0.4			MeCN						[DCC16]
6.	Molecule:100776	2.5E-5	[Ru(phen)3][PF6]2	0.4	TEOA	300	MeCN	Argon atmosphere					[DCC16]
7.	[Re(bpy)2(CO)2][OTf]	0.5	[Ru(bpy)3][PF6]	1	TEOA		DMA				15	115	[AiR19]
8.	[Re(bpy)2(CO)2][OTf]	0.01	[Ru(bpy)3][PF6]	1	TEOA		DMA				375	2750	[AiR19]
9.	[Re(bpy)2(CO)2][OTf]	0.1	[Ru(bpy)3][PF6]	1	TEOA		DMA				38	428	[AiR19]
10.	[Re(bpy)2(CO)2][OTf]	0.05	[Ru(bpy)3][PF6]	1	TEOA		DMA				50	535	[AiR19]
11.	[Re(bpy)2(CO)2][OTf]	1	[Ru(bpy)3][PF6]	1	TEOA		DMA				1.5	52	[AiR19]
12.	[Re(bpy)2(CO)2][OTf]	0.2	[Ru(bpy)3][PF6]	1	TEOA		DMA				24	275	[AiR19]
13.	[Re(bpy)2(CO)2][OTf]	0.02	[Ru(bpy)3][PF6]	1	TEOA		DMA				225	1480	[AiR19]
14.	[Re(bpy)2(CO)2][OTf]	1			TEOA		DMA					10.3	[AiR19]
15.	[Ni(bpy)-(MeNHC)2][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA 5% (v/v), H2O 2% (v/v)		10000	58000		[DSP19]
16.	[Ni(bpy)-(MeNHC)2][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA 5% (v/v), H2O 2% (v/v)		570000			[DSP19]
17.	[Ni(bpy-bNHCMe)][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA, H2O	8000	5000	34000		[DSP19]
18.	[Ni(bpy)-(MeNHC)2][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA	108000	4000	278000		[DSP19]
19.	[Ni(bpy-bNHCEt)][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA, H2O	175000	19000	29000		[DSP19]
20.	[Ni(bpy)-(MeNHC)2][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA, H2O	51000	12000			[DSP19]
21.	[Ni(bpy-bNHCMe)][PF6]2	2.0E-6	Ir(ppy)3	0.1	TEA		MeCN		5000	1000	15000		[DSP19]
22.	[Ni(bpy)-(MeNHC)2][PF6]2	2.0E-6	Ir(ppy)3	0.1	TEA		MeCN		130000	29000	4900000		[DSP19]
23.	[Ni(bpy-bNHCEt)][PF6]2	2.0E-6	Ir(ppy)3	0.1	TEA		MeCN		9000		36000		[DSP19]
24.	[Ni(bpy)-(MeNHC)2][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA, H2O	31000		320000		[DSP19]
25.	[Ni(bpy-bNHCMe)][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA	76000		17000		[DSP19]
26.	[Ni(bpy-bNHCEt)][PF6]2	2.0E-6	Ir(ppy)3	0.1	BIH	0.01	MeCN	TEA	310000		33000		[DSP19]
27.	Molecule:100968	0.2	Ru(bpy)3	0.2	BIH	0.1	MeCN		30349		1013		[ECD22]
28.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN		15520		86		[ECD22]
29.	Molecule:100968	2			BIH	0.1	MeCN		112		0		[ECD22]
30.	Molecule:100968	2	Ru(bpy)3	0.2			MeCN		150		0		[ECD22]
31.			Ru(bpy)3	0.2	BIH	0.1	MeCN		43		52		[ECD22]
32.	Molecule:100968	0.2	Molecule:100971	0.2	BIH	0.1	MeCN		28712		6527		[ECD22]
33.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN		15520		86		[ECD22]
34.	Molecule:100968	0.2	Ru(bpy)3	0.2	BIH	0.1	MeCN		30349		1013		[ECD22]
35.	Molecule:100968	2	Ir(ppy)3	0.2	BIH	0.1	MeCN		18502		141		[ECD22]
36.	Molecule:100968	2	Molecule:100970	0.2	BIH	0.1	MeCN		6710		0		[ECD22]
37.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN	Ar	0		222		[ECD22]
38.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN		6		0		[ECD22]
39.	Molecule:100968	2	Molecule:100971	0.2	BIH	0.1	MeCN		12749		163		[ECD22]
40.	Molecule:100968	2	Molecule:100970	0.2	BIH	0.1	MeCN		6710		0		[ECD22]
41.	Molecule:100968	0.2	Molecule:100971	0.2	BIH	0.1	MeCN		28712		6527		[ECD22]
42.	Molecule:100968	0.2	Ru(bpy)3	0.2	BIH	0.1	MeCN		30349		1013		[ECD22]
43.	Molecule:100968	2	Molecule:100971	0.2	BIH	0.1	MeCN		12749		163		[ECD22]
44.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN		15520		86		[ECD22]
45.			Ru(bpy)3	0.2	BIH	0.1	MeCN		43		52		[ECD22]
46.	Molecule:100968	2	Ir(ppy)3	0.2	BIH	0.1	MeCN		18502		141		[ECD22]
47.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN	Ar	0		222		[ECD22]
48.	Molecule:100968	2	Ru(bpy)3	0.2			MeCN		150		0		[ECD22]
49.	Molecule:100968	2	Ru(bpy)3	0.2	BIH	0.1	MeCN		6		0		[ECD22]
50.	Molecule:100968	2			BIH	0.1	MeCN		112		0		[ECD22]
51.	Molecule:100969	2	Molecule:100971	0.2	BIH	0.05	MeCN						[ECD22]
52.	Molecule:100969	2	Molecule:100971	0.2	BIH	0.05	MeCN						[ECD22]
53.	Molecule:100969	2	Molecule:100971	0.2	BIH	0.05	MeCN						[ECD22]
54.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	BIH	0.01	DMF	TEA	131				[EtF21]
55.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	BIH	0.005	DMF	TEA	78				[EtF21]
56.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.1	BIH	0.05	DMF	TEA	270				[EtF21]
57.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.005	BIH	0.01	DMF	TEA	124				[EtF21]
58.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.0125	BIH	0.01	DMF	TEA	144				[EtF21]
59.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	BIH	0.01	DMF	TEA	195				[EtF21]
60.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	BIH	0.02	DMF	TEA	134				[EtF21]
61.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	TEA	0.36	DMF		52				[EtF21]
62.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	[Cu(bcp)(xant)][PF6]	0.05	BIH	0.01	DMF	TEA	169				[EtF21]
63.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05			BIH	0.01	DMF	TEA	63				[EtF21]
64.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	BIH	0.02	DMF	TEA	193				[EtF21]
65.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.05	BIH	0.5	DMF	TEA	255				[EtF21]
66.	(tBuxant)-(Re(bpy)(CO)3Cl)2	0.05	Ir(fppy)3	0.025	BIH	0.01	DMF	TEA	149				[EtF21]
67.	Ru(dppq)(tpy)(MeCN)	0.04			BIH	0.1	DMA		58		1	3	[FIR18]
68.	Ru(dppq)(tpy)(MeCN)	0.04			TEOA		DMA					14	[FIR18]
69.	Mn(oMesbpy)(CO)2Br	0.05	[Cu(phen)-(dPPh-Bu)2]2[PF6]2	0.25	BIH	0.01	MeCN		208		0.5	5	[HEa18]
70.	Mn(bpy)(CO)3Br	0.05	[Cu(phen)-(dPPh-Bu)2]2[PF6]2	0.25	BIH	0.01	MeCN		50		4	157	[HEa18]
71.	Molecule:100845	0.05	[Cu(phen)-(dPPh-Bu)2]2[PF6]2	0.25	BIH	0.01	MeCN		164		1	65	[HEa18]
72.	[Co(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		0		2	1	[HEa16]
73.	[Co(qpy)(H2O)2][ClO4]2	0.01	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		1875		11	18	[HEa16]
74.	[Co(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.3			MeCN		114		25	25	[HEa16]
75.	[Co(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		366		15	4	[HEa16]
76.	[Co(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN	Argon atmosphere	0		3	1	[HEa16]
77.	[Co(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		182		0	11	[HEa16]
78.	[Co(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN	Argon atmosphere	0		33	0	[HEa16]
79.	[Co(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		2660		23	35	[HEa16]
80.	[Co(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		0		6	1	[HEa16]
81.	[Co(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		497		5	3	[HEa16]
82.	[Co(qpy)(H2O)2][ClO4]2	0.1	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		466		2	22	[HEa16]
83.	[Co(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.3			MeCN		0		1	1	[HEa16]
84.	Co(ClO4)2	0.05	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		33		11	1	[HEa16]
85.	[Co(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.5	BIH	0.1	MeCN		521		49	6	[HEa16]
86.	[Co(qpy)(H2O)2][ClO4]2	0.2	Ru(bpy)3Cl2	0.3	BIH	0.1	MeCN		1262		7	23	[HEa16]
87.	[Co(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.5	BIH	0.1	MeCN		136		43	5	[HEa16]
88.	[Co(qpy)(H2O)2][ClO4]2	0	purpurin	2	BIH	0.1	DMF		0		0	90	[HEa16]
89.	[Co(qpy)(H2O)2][ClO4]2	0.005	purpurin	2	BIH	0.1	DMF		790		11	78	[HEa16]
90.	[Co(qpy)(H2O)2][ClO4]2	0.05	purpurin	2	BIH	0.1	DMF		197		1	9	[HEa16]
91.	[Co(qpy)(H2O)2][ClO4]2	0.005	purpurin	2			DMF	Argon atmosphere	0		0	26	[HEa16]
92.	[Co(qpy)(H2O)2][ClO4]2	0.05	purpurin	0	BIH	0.1	DMF		27		0	4	[HEa16]
93.	[Co(qpy)(H2O)2][ClO4]2	0.005	purpurin	2	BIH	0.1	DMF	Argon atmosphere	0		226	167	[HEa16]
94.	Co(ClO4)2	0.05	purpurin	2	BIH	0.1	DMF		0		0	3	[HEa16]
95.	[Co(qpy)(H2O)2][ClO4]2	0.05	purpurin	2			DMF		0		0	3	[HEa16]
96.	[Co(qpy)(H2O)2][ClO4]2	0.05	purpurin	2	BIH	0.1	DMF	Argon atmosphere	0		78	6	[HEa16]
97.	[Fe(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN	Argon atmosphere	0		1	0	[HEa16]
98.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		1879		15	48	[HEa16]
99.	[Fe(qpy)(H2O)2][ClO4]2	0.02	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		2660		29	51	[HEa16]
100.	[Fe(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.05	BIH	0.1	MeCN		0		1	0	[HEa16]
101.	[Fe(qpy)(H2O)2][ClO4]2	0.01	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		3087		121	35	[HEa16]
102.	[Fe(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		3844		118	534	[HEa16]
103.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.05	BIH	0.1	MeCN		1336		10	34	[HEa16]
104.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN	Argon atmosphere	0		1	3	[HEa16]
105.	[Fe(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN		0		0	0	[HEa16]
106.	[Fe(qpy)(H2O)2][ClO4]2	0.02	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN	Argon atmosphere	0		0	0	[HEa16]
107.	[Fe(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.2			MeCN		160		8	22	[HEa16]
108.	[Fe(qpy)(H2O)2][ClO4]2	0.01	Ru(bpy)3Cl2	0.2	BIH	0.1	MeCN	Argon atmosphere	0		0	0	[HEa16]
109.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.05	BIH	0.1	MeCN		0		0	0	[HEa16]
110.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.2	BIH	0.1	DMF	Argon atmosphere	0		54	20	[HEa16]
111.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.02	BIH	0.1	DMF	Argon atmosphere	0		3	21	[HEa16]
112.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.02	BIH	0.1	DMF		520		0	14	[HEa16]
113.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.05	BIH	0.1	DMF	Argon atmosphere	0		0	8	[HEa16]
114.	[Fe(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.02	BIH	0.1	DMF		0		139	0	[HEa16]
115.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.02	BIH	0.1	DMF		0		0	8	[HEa16]
116.	[Fe(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.02	BIH	0.1	DMF		1365		0	115	[HEa16]
117.	[Fe(qpy)(H2O)2][ClO4]2	0.005	Ru(bpy)3Cl2	0.02	BIH	0.1	DMF	Argon atmosphere	0		52	88	[HEa16]
118.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.05	BIH	0.1	DMF		520		0	21	[HEa16]
119.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0	BIH	0.1	DMF		0		0	24	[HEa16]
120.	[Fe(qpy)(H2O)2][ClO4]2	0	Ru(bpy)3Cl2	0.05	BIH	0.1	DMF		0		0	10	[HEa16]
121.	[Fe(qpy)(H2O)2][ClO4]2	0.05	Ru(bpy)3Cl2	0.2	BIH	0.1	DMF		350		1	23	[HEa16]
122.	Molecule:100957	1.25E-5	[Ru(phen)3][PF6]2	0.4	TEOA	0.3	MeCN		51392				[Hea18]
123.	[Ir(dmbpy)(tpy)Cl][PF6]2	0.1			TEOA		MeCN		5		3	9	[Itb17]
124.	Molecule:100869	0.1			TEOA		MeCN		0		1	7	[Itb17]
125.	[Ir(dnbpy)(tpy)Cl][PF6]2	0.1			TEOA		MeCN		3		1	5	[Itb17]
126.	[Ir(bpy)(tpy)Cl][PF6]2	0.1			TEOA		MeCN		2		1	20	[Itb17]
127.	Fe(tpy-tol)Cl3	0.01	4CzIPN	0.05	TEA	0.28	DMF		2250				[Mao20]
128.	Mn(phdk)(CO)3(MeCN)		Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		7			40	[Mcm17]
129.	Mn(bpy)(CO)3Br		Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		47			15	[Mcm17]
130.	Mn(phdk)(CO)3Br		Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		8			52	[Mcm17]
131.	Mn(phdk)(CO)3Br		Ru(bpy)3Cl2	100			DMF		9			13	[Mcm17]
132.	Mn(phdk)(CO)3(MeCN)		Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		9			48	[Mcm17]
133.	Mn(phdk)(CO)3(MeCN)		Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		7			34	[Mcm17]
134.	Mn(phdk)(CO)3(MeCN)		Ru(bpy)3Cl2	200	BNAH	0.1	MeCN		8			52	[Mcm17]
135.	Mn(phen)(CO)3Br		Ru(bpy)3Cl2	100	BNAH	0.1	DMF		17			4	[Mcm17]
136.	Mn(bpy)(CO)3Br		Ru(bpy)3Cl2	100	BNAH	0.1	DMF		6			39	[Mcm17]
137.	Mn(phdk)(CO)3(MeCN)	2	Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		5			18	[Mcm17]
138.	Mn(phdk)(CO)3(MeCN)		Ru(bpy)3Cl2	100	BNAH	0.1	MeCN		15			58	[Mcm17]
139.	Mn(phdk)(CO)3Br		Ru(bpy)3Cl2	100	BNAH	0.1	DMF		21			22	[Mcm17]
140.	[Co(pabop)][ClO4]2	0.05	Ir(ppy)3	0.2	TEA		MeCN		270				[MCo15]
141.	[Fe(pabop)Cl2][CLO4]	0.05	Ir(ppy)3	0.2	TEA		MeCN					5	[MCo15]
142.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1	BIH	0.011	MeCN	TfOH	0.9				[Nip18]
143.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1	BIH	0.011	MeCN	TEA	10.6				[Nip18]
144.	[Ni(py)-(MeNHC)2(MeCN)][PF6]2	0.1	Ir(ppy)3	0.1	BIH	0.011	MeCN	TEA	0.1				[Nip18]
145.	[Ni(py)-(MeNHC)2(MeCN)][PF6]2	0.1	Ir(ppy)3	0.1	BIH	0.011	DMF	TEA	0.5				[Nip18]
146.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1	BIH	0.011	MeCN	proton sponge	5.6				[Nip18]
147.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1	BIH	0.011	DMF	TEA	9				[Nip18]
148.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1	BIH	0.011	MeCN		1.8				[Nip18]
149.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1			MeCN	TEA	0.3				[Nip18]
150.	Ni(4O(-)py)-(MeNHC)2Cl	0.1			BIH	0.011	MeCN	TEA	0.6				[Nip18]
151.	Ni(4O(-)py)-(MeNHC)2Cl	0.1	Ir(ppy)3	0.1	BIH	0.011	MeCN	N2	0.2				[Nip18]
152.	[Fe(pTMAPP)Cl][PF6]4	0.002	Molecule:100762	0.2	BIH	0.005	MeCN	TFE	115				[PSC22]
153.	[Fe(pTMAPP)Cl][PF6]4	0.002	Molecule:100764	0.2	BIH	0.005	MeCN	TFE	32		57		[PSC22]
154.	[Fe(pTMAPP)Cl][PF6]4	0.002	Molecule:100763	0.2	BIH	0.005	MeCN	TFE	112		12		[PSC22]
155.	[Fe(pTMAPP)Cl][PF6]4	0.002	Molecule:100765	0.2	BIH	0.005	MeCN	TFE	89				[PSC22]
156.	[Fe(pTMAPP)Cl][PF6]4	0.002	Molecule:100761	0.2	BIH	0.005	MeCN	TFE	88		12		[PSC22]
157.	[Fe(pTMAPP)Cl][PF6]4	0.002	Molecule:100493	0.2	BIH	0.005	MeCN	TFE	103		25		[PSC22]
158.	[Ir(mesbpy-(PCy2)2)][BPh4]	0.02			BIH	0.2	DMA		470		15	2080	[PCR20]
159.	[Ru(bpy)(py)-(tBuNHC)2CO][PF6]2	0.01	[Ru(dmb)3][PF6]2	0.05	BI(OH)H	0.1	DMA		129		505	3792	[PCR20]
160.	[Ru(bpy)(py)-(MeNHC)2(MeCN)][PF6]2	0.01	[Ru(dmb)3][PF6]2	0.05	BI(OH)H	0.1	DMA		224		1438	4593	[PCR20]
161.	[Ru(bpy)(py)-(tBuNHC)2(MeCN)][PF6]2	0.01	[Ru(dmb)3][PF6]2	0.05	BI(OH)H	0.1	DMA		129		556	3296	[PCR20]
162.	[Ru(bpy)(py)-(MeNHC)2CO][PF6]2	0.01	[Ru(dmb)3][PF6]2	0.05	BI(OH)H	0.1	DMA		300		1897	5634	[PCR20]
163.	Mn(bpy)(CO)3Br	0.05	[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	MeCN		40		17	78	[PCr14]
164.	Mn(bpy)(CO)3Br	0.05	[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMF		8		1	67	[PCr14]
165.			[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMF		1		4	8	[PCr14]
166.	Mn(bpy)(CO)3Br	0.05	Ru(bpy)3	0.05	BNAH	0.1	DMF		12		8	157	[PCr14]
167.			[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMF		3		11	25	[PCr14]
168.	Mn(bpy)(CO)3Br	0.05	[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMF		12		14	149	[PCr14]
169.	Mn(bpy)(CO)3Br	0.05	[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMF	Argon gas	2		49	4	[PCr14]
170.	Mn(bpy)(CO)3Br	0.05	[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMA		9		14	98	[PCr14]
171.			[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	DMA		3		7	19	[PCr14]
172.			[Ru(dmb)3][PF6]2	0.05	BNAH	0.1	MeCN		2		12	14	[PCr14]
173.	Fe(DHPP)Cl	0.0006	Molecule:100932	0.02	BIH	0.06	DMF		21616				[PCr23]
174.	Molecule:100941	0.1	Molecule:100940	1	BIH	0.1	MeCN		80		33		[PRo22]
175.	Molecule:100941	0.1	Molecule:100940	1	BIH	0.02	MeCN		100		43		[PRo22]
176.	Molecule:100941	0.1			BIH	0.02	MeCN		0		0		[PRo22]
177.	Molecule:100941	0.1	Molecule:100940	1	BIH	0.02	MeCN		0		0		[PRo22]
178.	Molecule:100941	0.01	Molecule:100940	1	BIH	0.02	MeCN		576		287		[PRo22]
179.	Molecule:100941	0.1	Molecule:100940	1	BIH	0.02	MeCN		3.2		1.6		[PRo22]
180.	Mn(CN)(bpy)(CO)3	1	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	MeCN		4.2		0.8	1.4	[PRo16]
181.	Mn(CN)(bpy)(CO)3	1	[Ru(dmb)3][PF6]2	1	BNAH	0.1	DMF		2.3		0.37	9.5	[PRo16]
182.	Mn(CN)(bpy)(CO)3	1	[Ru(dmb)3][PF6]2	1	BNAH	0.1	DMF		0.83		0.0073	5.2	[PRo16]
183.	Mn(CN)(bpy)(CO)3	1	[Ru(dmb)3][PF6]2	1	BNAH	0.1	MeCN		3.2		0.17	1.2	[PRo16]
184.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF		3.2		0.45	21	[PRo16]
185.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	MeCN		19		1.4	8.1	[PRo16]
186.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	1	BNAH	0.1	MeCN		21		1.3	9	[PRo16]
187.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF		0.92		0.25	11	[PRo16]
188.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF		9.1		1.2	130	[PRo16]
189.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	MeCN		5.9		0.24	2.1	[PRo16]
190.	Mn(CN)(bpy)(CO)3	1	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF		3		0.24	5.8	[PRo16]
191.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	0.1	BNAH	0.1	MeCN		7.9		0.56	4.5	[PRo16]
192.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	MeCN		3.4		0.14		[PRo16]
193.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	1	BNAH	0.1	DMF		7.1		1.6	130	[PRo16]
194.	Mn(CN)(bpy)(CO)3	1	[Ru(dmb)3][PF6]2	1	BNAH	0.1	MeCN		3.1		0.14		[PRo16]
195.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	0.1	BNAH	0.1	MeCN		4.7		0.27		[PRo16]
196.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	0.1	BNAH	0.1	DMF		3.9		0.64	36	[PRo16]
197.	Mn(CN)(bpy)(CO)3	0.1	[Ru(dmb)3][PF6]2	0.1	BNAH	0.1	DMF		2.8		0.2	16	[PRo16]
198.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF		2.2				[PRo16]
199.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF	Argon gas				2.6	[PRo16]
200.	Mn(CN)(bpy)(CO)3	0.5	[Ru(dmb)3][PF6]2	0.5	BNAH	0.1	DMF	Argon gas	2.4		1.4		[PRo16]

Category:Homogeneous electrochemical CO2 conversion

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