Rhenium(I) trinuclear rings as highly efficient redox photosensitizers for photocatalytic CO2 reduction: Difference between revisions
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{{DOI|doi=10.1039/c6sc01913g | {{DOI|doi=10.1039/c6sc01913g}} | ||
===Abstract=== | ===Abstract=== | ||
==== Summary==== | ==== Summary==== | ||
A photochemical reduction of CO<sub>2</sub> to CO or formic acid was shown using the bipyridine-based rhenium, ruthenium and manganese catalysts {{#moleculelink:|link=NZCMNMSVXYOMGS-UHFFFAOYSA-N|image=false|width=300|height=200}}, {{#moleculelink:|link=XUQJAKJUMNDNTK-UHFFFAOYSA-L|image=false|width=300|height=200}} or {{#moleculelink: |link=OMERWMHUIAGAOR-UHFFFAOYSA-N|image=false|width=300|height=200}} in combination with cyclic rhenium-based trinuclear redox photosensitizers. Turnover numbers (TONs) of up to 290 for formic acid were reached in DMA with the ruthenium complex {{#moleculelink:|link=XUQJAKJUMNDNTK-UHFFFAOYSA-L|image=false|width=300|height=200}} and photosensitizer {{#moleculelink:|link= | A photochemical reduction of CO<sub>2</sub> to CO or formic acid was shown using the bipyridine-based rhenium, ruthenium and manganese catalysts {{#moleculelink:|link=NZCMNMSVXYOMGS-UHFFFAOYSA-N|image=false|width=300|height=200}}, {{#moleculelink: |link=XUQJAKJUMNDNTK-UHFFFAOYSA-L|image=false|width=300|height=200}} or {{#moleculelink: |link=OMERWMHUIAGAOR-UHFFFAOYSA-N|image=false|width=300|height=200}} in combination with cyclic rhenium-based trinuclear redox photosensitizers. Turnover numbers (TONs) of up to 290 for formic acid were reached in DMA with the ruthenium complex {{#moleculelink: |link=XUQJAKJUMNDNTK-UHFFFAOYSA-L|image=false|width=300|height=200}} and photosensitizer {{#moleculelink: |link=JLRZSCLFGATQEH-UHFFFAOYSA-T|image=false|width=300|height=200}}. For CO production, TONs of up to 98 were obtained in DMF with the rhenium complex {{#moleculelink:|link=NZCMNMSVXYOMGS-UHFFFAOYSA-N|image=false|width=300|height=200}} and photosensitizer {{#moleculelink: |link=LKSLWZSWOWNWCR-UHFFFAOYSA-T|image=false|width=300|height=200}}. The experiments were conducted under visible-light irradiation (λ = 436 nm) using TEOA as sacrificial electron donor (see section SEDs below). | ||
====Advances and special progress==== | ====Advances and special progress==== | ||
Re(I)-based trinuclear photosensitizers were developed and allowed for high product selectivities for CO or formic acid in CO<sub>2</sub> reduction attempts with different bipyridine-based catalysts. | Re(I)-based trinuclear photosensitizers were developed and allowed for high product selectivities for CO or formic acid in CO<sub>2</sub> reduction attempts with different bipyridine-based catalysts. | ||
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M V30 END CTAB | M V30 END CTAB | ||
M END | M END | ||
</chemform><chemform smiles=" | </chemform><chemform smiles="CC(C)(C)C1=CC2=N(~[Ru](~Cl)(~Cl)(~C#O)(~C#O)~N3=C2C=C(C(C)(C)C)C=C3)C=C1" inchikey="XUQJAKJUMNDNTK-UHFFFAOYSA-L" inchi="InChI=1S/C18H24N2.2CO.2ClH.Ru/c1-17(2,3)13-7-9-19-15(11-13)16-12-14(8-10-20-16)18(4,5)6;2*1-2;;;/h7-12H,1-6H3;;;2*1H;/q;;;;;+2/p-2" float="none" width="200" height="200"> | ||
RDKit 2D | |||
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M V30 COUNTS 27 29 0 0 0 | M V30 COUNTS 27 29 0 0 0 | ||
M V30 BEGIN ATOM | M V30 BEGIN ATOM | ||
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M V30 5 C | M V30 5 C 3.05985 -5.93002 0 0 | ||
M V30 6 C | M V30 6 C 3.92882 -6.42503 0 0 | ||
M V30 7 C 6. | M V30 7 C 6.75985 -2.90007 0 0 | ||
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M V30 11 C | M V30 11 C 6.75985 -3.90502 0 0 | ||
M V30 12 | M V30 12 N 7.62882 -4.40003 0 0 | ||
M V30 13 Ru | M V30 13 Ru 6.85 -6.2 0 0 | ||
M V30 14 | M V30 14 Cl 9.15 -5.55 0 0 | ||
M V30 15 | M V30 15 Cl 5.675 -7.425 0 0 | ||
M V30 16 C | M V30 16 C 7.10882 -7.16593 0 0 | ||
M V30 17 C | M V30 17 C 7.71603 -6.7 0 0 | ||
M V30 18 O | M V30 18 O 7.62671 -8.02303 0 0 | ||
M V30 19 O | M V30 19 O 8.74102 -6.675 0 0 | ||
M V30 20 | M V30 20 C 2.19382 -4.42507 0 0 | ||
M V30 21 | M V30 21 C 2.94382 -3.12603 0 0 | ||
M V30 22 C | M V30 22 C 1.44382 -5.72411 0 0 | ||
M V30 23 C | M V30 23 C 0.89478 -3.67507 0 0 | ||
M V30 24 C | M V30 24 C 7.62664 -1.39997 0 0 | ||
M V30 25 C | M V30 25 C 9.12664 -1.39997 0 0 | ||
M V30 26 C | M V30 26 C 6.12664 -1.39997 0 0 | ||
M V30 27 C | M V30 27 C 7.62664 0.10003 0 0 | ||
M V30 END ATOM | M V30 END ATOM | ||
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| Line 124: | Line 124: | ||
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M V30 END CTAB | M V30 END CTAB | ||
| Line 240: | Line 240: | ||
====Photosensitizer ==== | ====Photosensitizer ==== | ||
<chemform smiles="C1C=C2P(C3C=CC=CC=3)(C3C=CC=CC=3)~[Re+]3(N4=C(C5N3=CC([*])=C([*])C=5)C=C([*])C([*])=C4)([C-]#[O+])([C-]#[O+])~P(C3C=CC=CC=3)(C3C=CC=CC=3)C3C=CC(P(C4C=CC=CC=4)(C4C=CC=CC=4)~[Re+]4(N5=C(C6N4=CC([*])=C([*])C=6)C=C([*])C([*])=C5)([C-]#[O+])([C-]#[O+])~P(C4C=CC=CC=4)(C4C=CC=CC=4)C4C=CC(P(C5C=CC=CC=5)(C5C=CC=CC=5)~[Re+]5(N6=CC([*])=C([*])C=C6C6C=C([*])C([*])=CN=65)([C-]#[O+])([C-]#[O+])~P(C5C=CC=CC=5)(C5C=CC=CC=5)C=1C=C2)=CC=4)=CC=3" | <chemform smiles="C1C=C2P(C3C=CC=CC=3)(C3C=CC=CC=3)~[Re+]3(N4=C(C5N3=CC([*])=C([*])C=5)C=C([*])C([*])=C4)([C-]#[O+])([C-]#[O+])~P(C3C=CC=CC=3)(C3C=CC=CC=3)C3C=CC(P(C4C=CC=CC=4)(C4C=CC=CC=4)~[Re+]4(N5=C(C6N4=CC([*])=C([*])C=6)C=C([*])C([*])=C5)([C-]#[O+])([C-]#[O+])~P(C4C=CC=CC=4)(C4C=CC=CC=4)C4C=CC(P(C5C=CC=CC=5)(C5C=CC=CC=5)~[Re+]5(N6=CC([*])=C([*])C=C6C6C=C([*])C([*])=CN=65)([C-]#[O+])([C-]#[O+])~P(C5C=CC=CC=5)(C5C=CC=CC=5)C=1C=C2)=CC=4)=CC=3.[P-](F)(F)(F)(F)(F)F.[P-](F)(F)(F)(F)(F)F.[P-](F)(F)(F)(F)(F)F" inchikey="" inchi="" float="none" width="200" height="200" r1="H,CH3,CH3,H" r2="CH3,H,CH3,OMe"> | ||
-INDIGO- | -INDIGO-02262410222D | ||
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M V30 BEGIN ATOM | M V30 BEGIN ATOM | ||
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| Line 406: | Line 406: | ||
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| Line 591: | Line 612: | ||
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M V30 183 1 135 159 | M V30 183 1 135 159 | ||
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M V30 186 1 160 163 | |||
M V30 187 1 160 164 | |||
M V30 188 1 160 165 | |||
M V30 189 1 160 166 | |||
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M V30 191 1 167 169 | |||
M V30 192 1 167 170 | |||
M V30 193 1 167 171 | |||
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M V30 195 1 167 173 | |||
M V30 196 1 174 175 | |||
M V30 197 1 174 176 | |||
M V30 198 1 174 177 | |||
M V30 199 1 174 178 | |||
M V30 200 1 174 179 | |||
M V30 201 1 174 180 | |||
M V30 END BOND | M V30 END BOND | ||
M V30 END CTAB | M V30 END CTAB | ||
| Line 602: | Line 641: | ||
==== Additives==== | ==== Additives==== | ||
In this study, no additives were tested. | In this study, no additives were tested. | ||
[[Category:Photocatalytic CO2 conversion to HCOOH]] | [[Category:Photocatalytic CO2 conversion to HCOOH]][[Category:Publication]] | ||
Latest revision as of 13:46, 3 May 2024
Abstract[edit | edit source]
Summary[edit | edit source]
A photochemical reduction of CO2 to CO or formic acid was shown using the bipyridine-based rhenium, ruthenium and manganese catalysts [Re(bpy)(CO)3(MeCN)][PF6], Ru(dtBubpy)(CO)2Cl2 or [Mn(dtBubpy)(CO)3(MeCN)][PF6] in combination with cyclic rhenium-based trinuclear redox photosensitizers. Turnover numbers (TONs) of up to 290 for formic acid were reached in DMA with the ruthenium complex Ru(dtBubpy)(CO)2Cl2 and photosensitizer 100877. For CO production, TONs of up to 98 were obtained in DMF with the rhenium complex [Re(bpy)(CO)3(MeCN)][PF6] and photosensitizer 100878. The experiments were conducted under visible-light irradiation (λ = 436 nm) using TEOA as sacrificial electron donor (see section SEDs below).
Advances and special progress[edit | edit source]
Re(I)-based trinuclear photosensitizers were developed and allowed for high product selectivities for CO or formic acid in CO2 reduction attempts with different bipyridine-based catalysts.
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 or formic acid under visible-light catalysis using bipyridine-based complexes and rhenium-based trinuclear rings as photosensitizers. The catalytic system performs best in DMA for formic acid production (referring to the TON of formic acid production) and in DMF for CO production.
Catalyst[edit | edit source]
[Re(bpy)(CO)3(MeCN)][PF6]
Ru(dtBubpy)(CO)2Cl2
[Mn(dtBubpy)(CO)3(MeCN)][PF6]
Photosensitizer[edit | edit source]
Investigation[edit | edit source]
| cat | cat conc [µM] | PS | PS conc [mM] | solvent A | . | . | λexc [nm] | . | TON CO | . | . | . | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1. | 0.05 | 0.05 | 436 | 27 | |||||||||
| 2. | 0.05 | 0.05 | 436 | 98 | |||||||||
| 3. | 0.05 | 0.05 | 436 | 22 | |||||||||
| 4. | 0.05 | 0.05 | 436 | 71 | |||||||||
| 5. | 0.05 | 436 | 6 | ||||||||||
| 6. | 0.05 | 436 | 8 | ||||||||||
| 7. | 0.05 | 0.05 | 436 | 20 | |||||||||
| 8. | 0.05 | 0.05 | 436 | 32 | |||||||||
| 9. | 0.05 | 0.05 | 436 | 11 | |||||||||
| 10. | 0.05 | 0.05 | 436 | 48 |
Investigation-Name: Table 1
| cat | cat conc [µM] | PS | PS conc [mM] | e-D | e-D conc [M] | solvent A | . | . | λexc [nm] | . | TON CO | TON H2 | TON HCOOH | . | . | . | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1. | 0.05 | 0.05 | 436 | 20 | 72 | 290 | |||||||||||
| 2. | 0.05 | 0.05 | 0.03 | 436 | 16 | 49 | 280 | ||||||||||
| 3. | 0.05 | 0.05 | 436 | 32 | 85 | ||||||||||||
| 4. | 0.05 | 0.05 | 0.03 | 436 | 80 | 60 |
Investigation-Name: Table 2
Sacrificial Electron Donor[edit | edit source]
In this study, the experiments were done with the sacrificial electron donor TEOA (100507).
Additives[edit | edit source]
In this study, no additives were tested.
