Highly Efficient and Selective Photocatalytic CO2 Reduction by Iron and Cobalt Quaterpyridine Complexes: Difference between revisions

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DOI 10.1021/jacs.6b06002
Authors Zhenguo Guo, Siwei Cheng, Claudio Cometto, Elodie Anxolabéhère-Mallart, Siu-Mui Ng, Chi-Chiu Ko, Guijian Liu, Lingjing Chen, Marc Robert, Tai-Chu Lau,
Submitted 22.07.2016
Published online 26.07.2016
Licenses -
Subjects Colloid and Surface Chemistry, Biochemistry, General Chemistry, Catalysis
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{{#doiinfobox: 10.1021/jacs.6b06002}}  
{{DOI|doi=10.1021/jacs.6b06002}}  
[[Category:Photocatalytic CO2 conversion to CO]]
[[Category:Photocatalytic CO2 conversion to CO]]
{{BaseTemplate}}
{{BaseTemplate}}
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===Abstract===
===Abstract===
====Summary====
====Summary====
A photochemical reduction of CO<sub>2</sub> to CO was shown using the cobalt complex {{#moleculelink:|link=NLKWUAXOGCKGEY-UHFFFAOYSA-L|image=false|width=300|height=200}} or the iron complex {{#moleculelink:|link=OZQYFMFOIFRRLI-UHFFFAOYSA-L|image=false|width=300|height=200}} as catalysts in combination with the ruthenium-based photosensitizer {{#moleculelink:|link=SJFYGUKHUNLZTK-UHFFFAOYSA-L|image=false|width=300|height=200}}. Turnover numbers (TONs) up to 2660 and a selectivity of 98% for CO using the cobalt catalyst and TONs of >3000 and a selectivity of 95% for CO using the iron catalyst were reached in acetonitrile/triethanolamine. When swapping the ruthenium photosensitizer for the organic dye sensitizer {{#moleculelink:|link=BBNQQADTFFCFGB-UHFFFAOYSA-N|image=false|width=300|height=200}}, TONs of 790 and 1365 in DMF were obtained for the cobalt and iron catalysts, respectively. The experiments were conducted under visible-light irradiation (λ = 460 nm) using BIH as sacrificial reductants (see section SEDs below).   
A photochemical reduction of CO<sub>2</sub> to CO was shown using the cobalt complex {{#moleculelink:|link=NLKWUAXOGCKGEY-UHFFFAOYSA-L|image=false|width=300|height=200}} or the iron complex {{#moleculelink:|link=OZQYFMFOIFRRLI-UHFFFAOYSA-L|image=false|width=300|height=200}} as catalysts in combination with the ruthenium-based photosensitizer {{#moleculelink:|link=SJFYGUKHUNLZTK-UHFFFAOYSA-L|image=false|width=300|height=200}}. Turnover numbers (TONs) up to 2660 and a selectivity of 98% for CO using the cobalt catalyst and TONs of >3000 and a selectivity of 95% for CO using the iron catalyst were reached in acetonitrile/triethanolamine. When swapping the ruthenium photosensitizer for the organic dye sensitizer {{#moleculelink:|link=BBNQQADTFFCFGB-UHFFFAOYSA-N|image=false|width=300|height=200}}, TONs of 790 and 1365 in DMF were obtained for the cobalt and iron catalysts, respectively. The experiments were conducted under visible-light irradiation (λ = 460 nm) using BIH as sacrificial reductant (see section SEDs below).   
==== Advances and special progress====
==== Advances and special progress====
The photocatalytic reduction of CO<sub>2</sub> to CO by cobalt and iron complexes was shown with some of the highest TONs for homogeneous photocatalytic CO2 reduction at that time and the (back then) highest TON for a system of fully earth-abundant materials was achieved.
The photocatalytic reduction of CO<sub>2</sub> to CO by cobalt and iron complexes was shown with some of the highest TONs for homogeneous photocatalytic CO<sub>2</sub> reduction at that time and the (back then) highest TON for a system of fully earth-abundant materials was achieved.


====Additional remarks====
====Additional remarks====
===Content of the published article in detail===
===Content of the published article in detail===
The article contains results for the reduction of CO<sub>2</sub> to CO under visible-light catalysis using cobalt and iron quaterpyridine complexes as catalysts. The catalytic system performs best (referring to the TON of CO production) in acetonitrile/triethanolamine using the cobalt complex and the ruthenium photosensitizer.  
The article contains results for the reduction of CO<sub>2</sub> to CO under visible-light catalysis using cobalt and iron quaterpyridine complexes as catalysts. The catalytic system performs best (referring to the TON of CO production) in acetonitrile/triethanolamine using the cobalt complex {{#moleculelink:|link=OZQYFMFOIFRRLI-UHFFFAOYSA-L|image=false|width=300|height=200}} and the ruthenium photosensitizer.  
==== Catalysts ====
==== Catalysts ====
<chemform smiles="C1C2C3C=CC=C4C5C=CC=C6C7C=CC=CN=7[Fe+2](O)(O)(N=34)(N=56)N=2C=CC=1.Cl([O-])(=O)(=O)=O.Cl([O-])(=O)(=O)=O" inchi="1S/C20H14N4.2ClHO4.Fe.2H2O/c1-3-13-21-15(7-1)17-9-5-11-19(23-17)20-12-6-10-18(24-20)16-8-2-4-14-22-16;2*2-1(3,4)5;;;/h1-14H;2*(H,2,3,4,5);;2*1H2/q;;;+2;;/p-2" inchikey="NLKWUAXOGCKGEY-UHFFFAOYSA-L" height="200px" width="300px" float="none">
<chemform smiles="C1C2C3C=CC=C4C5C=CC=C6C7C=CC=CN=7[Fe+2](O)(O)(N=34)(N=56)N=2C=CC=1.Cl([O-])(=O)(=O)=O.Cl([O-])(=O)(=O)=O" inchi="1S/C20H14N4.2ClHO4.Fe.2H2O/c1-3-13-21-15(7-1)17-9-5-11-19(23-17)20-12-6-10-18(24-20)16-8-2-4-14-22-16;2*2-1(3,4)5;;;/h1-14H;2*(H,2,3,4,5);;2*1H2/q;;;+2;;/p-2" inchikey="NLKWUAXOGCKGEY-UHFFFAOYSA-L" height="200px" width="300px" float="none">
Line 379: Line 379:
==== Investigations ====
==== Investigations ====


{{#experimentlist:|form=Photocatalytic_CO2_conversion_experiments|name=Co(qpy)(H2O)2(ClO4)2 and Ru(bpy)3Cl2}}
{{#experimentlist: |form=Photocatalytic_CO2_conversion_experiments|name=Optimizations of conditions for Co(qpy)(H2O)2(ClO4)2 and Ru(bpy)3Cl2}}


{{#experimentlist:|form=Photocatalytic_CO2_conversion_experiments|name=Fe(qpy)(H2O)2(ClO4)2 and Ru(bpy)3Cl2}}
{{#experimentlist: |form=Photocatalytic_CO2_conversion_experiments|name=Optimizations of conditions for Fe(qpy)(H2O)2(ClO4)2 and Ru(bpy)3Cl2}}


{{#experimentlist:|form=Photocatalytic_CO2_conversion_experiments|name=Co(qpy)(H2O)2(ClO4)2 and purpurin}}
{{#experimentlist: |form=Photocatalytic_CO2_conversion_experiments|name=Optimizations of conditions for Co(qpy)(H2O)2(ClO4)2 and purpurin}}


{{#experimentlist:|form=Photocatalytic_CO2_conversion_experiments|name=Fe(qpy)(H2O)2(ClO4)2}}
{{#experimentlist: |form=Photocatalytic_CO2_conversion_experiments|name=Optimizations of conditions for Fe(qpy)(H2O)2(ClO4)2}}


==== Sacrificial electron donor ====
==== Sacrificial electron donor ====
In this study, the experiments were done with the sacrificial reductant BIH ([[Molecule:100508|100508]]).
In this study, the experiments were done with the sacrificial reductant BIH ([[Molecule:100508|100508]]).
==== Additives====
==== Additives====
In this study, control experiments were conducted under an argon atmosphere.
In this study, control experiments were conducted under an argon atmosphere.[[Category:Publication]]

Latest revision as of 09:55, 22 May 2024


Abstract[edit | edit source]

Summary[edit | edit source]

A photochemical reduction of CO2 to CO was shown using the cobalt complex [Fe(qpy)(H2O)2][ClO4]2 or the iron complex [Co(qpy)(H2O)2][ClO4]2 as catalysts in combination with the ruthenium-based photosensitizer Ru(bpy)3Cl2. Turnover numbers (TONs) up to 2660 and a selectivity of 98% for CO using the cobalt catalyst and TONs of >3000 and a selectivity of 95% for CO using the iron catalyst were reached in acetonitrile/triethanolamine. When swapping the ruthenium photosensitizer for the organic dye sensitizer purpurin, TONs of 790 and 1365 in DMF were obtained for the cobalt and iron catalysts, respectively. The experiments were conducted under visible-light irradiation (λ = 460 nm) using BIH as sacrificial reductant (see section SEDs below).

Advances and special progress[edit | edit source]

The photocatalytic reduction of CO2 to CO by cobalt and iron complexes was shown with some of the highest TONs for homogeneous photocatalytic CO2 reduction at that time and the (back then) highest TON for a system of fully earth-abundant materials was achieved.

Additional remarks[edit | edit source]

Content of the published article in detail[edit | edit source]

The article contains results for the reduction of CO2 to CO under visible-light catalysis using cobalt and iron quaterpyridine complexes as catalysts. The catalytic system performs best (referring to the TON of CO production) in acetonitrile/triethanolamine using the cobalt complex [Co(qpy)(H2O)2][ClO4]2 and the ruthenium photosensitizer.

Catalysts[edit | edit source]

[Fe(qpy)(H2O)2][ClO4]2 [Co(qpy)(H2O)2][ClO4]2 Co(ClO4)2

Photosensitizers[edit | edit source]

Ru(bpy)3Cl2 purpurin

Investigations[edit | edit source]

catcat conc [µM]PSPS conc [mM]e-De-D conc [M]..solvent Aadditivesλexc [nm].TON COTON H2TON HCOOH.
1.

[Co(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)26602335
2.

[Co(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)021
3.

[Co(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

Argon atmosphere460 (LED)0330
4.

[Co(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)182011
5.

[Co(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.3


MeCN

460 (LED)1142525
6.

[Co(qpy)(H2O)2][ClO4]2

0.01

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)18751118
7.

[Co(qpy)(H2O)2][ClO4]2

0.2

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)1262723
8.

[Co(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)49753
9.

[Co(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.3


MeCN

460 (LED)011
10.

[Co(qpy)(H2O)2][ClO4]2

0.1

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)466222
11.

[Co(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.5

BIH

0.1

MeCN

460 (LED)521496
12.

[Co(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.5

BIH

0.1

MeCN

460 (LED)136435
13.

[Co(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)366154
14.

[Co(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

Argon atmosphere460 (LED)031
15.

[Co(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)061
16.

Co(ClO4)2

0.05

Ru(bpy)3Cl2

0.3

BIH

0.1

MeCN

460 (LED)33111
17.

[Co(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.3


MeCN

460 (LED)011
catcat conc [µM]PSPS conc [mM]e-De-D conc [M]solvent A..additivesλexc [nm].TON COTON H2TON HCOOH.
1.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)18791548
2.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

Argon atmosphere460 (LED)013
3.

[Fe(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)000
4.

[Fe(qpy)(H2O)2][ClO4]2

0.02

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)26602951
5.

[Fe(qpy)(H2O)2][ClO4]2

0.02

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

Argon atmosphere460 (LED)000
6.

[Fe(qpy)(H2O)2][ClO4]2

0.01

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)308712135
7.

[Fe(qpy)(H2O)2][ClO4]2

0.01

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

Argon atmosphere460 (LED)000
8.

[Fe(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

460 (LED)3844118534
9.

[Fe(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.2

BIH

0.1

MeCN

Argon atmosphere460 (LED)010
10.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.05

BIH

0.1

MeCN

460 (LED)13361034
11.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.05

BIH

0.1

MeCN

460 (LED)000
12.

[Fe(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.05

BIH

0.1

MeCN

460 (LED)010
13.

[Fe(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.2


MeCN

460 (LED)160822
catcat conc [µM]PSPS conc [mM]e-De-D conc [M]solvent Aadditivesλexc [nm].TON COTON H2TON HCOOH.
1.

[Co(qpy)(H2O)2][ClO4]2

0.05

purpurin

2

BIH

0.1

DMF

460 (LED)19719
2.

[Co(qpy)(H2O)2][ClO4]2

0.05

purpurin

2

BIH

0.1

DMF

Argon atmosphere460 (LED)0786
3.

[Co(qpy)(H2O)2][ClO4]2

0

purpurin

2

BIH

0.1

DMF

460 (LED)0090
4.

[Co(qpy)(H2O)2][ClO4]2

0.05

purpurin

0

BIH

0.1

DMF

460 (LED)2704
5.

[Co(qpy)(H2O)2][ClO4]2

0.05

purpurin

2


DMF

460 (LED)003
6.

[Co(qpy)(H2O)2][ClO4]2

0.005

purpurin

2

BIH

0.1

DMF

460 (LED)7901178
7.

[Co(qpy)(H2O)2][ClO4]2

0.005

purpurin

2

BIH

0.1

DMF

Argon atmosphere460 (LED)0226167
8.

[Co(qpy)(H2O)2][ClO4]2

0.005

purpurin

2


DMF

Argon atmosphere460 (LED)0026
9.

Co(ClO4)2

0.05

purpurin

2

BIH

0.1

DMF

460 (LED)003
catcat conc [µM]PSPS conc [mM]e-De-D conc [M]solvent Aadditivesλexc [nm].TON COTON H2TON HCOOH.
1.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.02

BIH

0.1

DMF

460 (LED)520014
2.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.02

BIH

0.1

DMF

Argon atmosphere460 (LED)0321
3.

[Fe(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.02

BIH

0.1

DMF

460 (LED)01390
4.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.05

BIH

0.1

DMF

460 (LED)520021
5.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.05

BIH

0.1

DMF

Argon atmosphere460 (LED)008
6.

[Fe(qpy)(H2O)2][ClO4]2

0

Ru(bpy)3Cl2

0.05

BIH

0.1

DMF

460 (LED)0010
7.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.2

BIH

0.1

DMF

460 (LED)350123
8.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.2

BIH

0.1

DMF

Argon atmosphere460 (LED)05420
9.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0

BIH

0.1

DMF

460 (LED)0024
10.

[Fe(qpy)(H2O)2][ClO4]2

0.05

Ru(bpy)3Cl2

0.02

BIH

0.1

DMF

460 (LED)008
11.

[Fe(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.02

BIH

0.1

DMF

460 (LED)13650115
12.

[Fe(qpy)(H2O)2][ClO4]2

0.005

Ru(bpy)3Cl2

0.02

BIH

0.1

DMF

Argon atmosphere460 (LED)05288

Sacrificial electron donor[edit | edit source]

In this study, the experiments were done with the sacrificial reductant BIH (100508).

Additives[edit | edit source]

In this study, control experiments were conducted under an argon atmosphere.

Investigations