CO2 conversion to CO: Difference between revisions

From ChemWiki
No edit summary
Line 379: Line 379:




<chemform smiles="" inchi="" inchikey="" height="200px" width="300px" float="none">  -INDIGO-07072219232D
<chemform smiles="" inchi="" inchikey="" height="200px" width="300px" float="none">  
  -INDIGO-07072219232D


   0  0  0  0  0  0  0  0  0  0  0 V3000
   0  0  0  0  0  0  0  0  0  0  0 V3000

Revision as of 08:34, 4 January 2023

Importance/relevance

Reduction of CO2 into energy-rich compounds is an important topic that can simultaneously tackle the shortage of fossil-fuel resources and global warming.36,40,42,288 Photocatalytic CO2 reduction utilizing solar light as an energy source has been widely investigated as a key technology for the conversion of abundant solar energy to chemical energy, so-called artificial photosynthesis.

General principles

Photosensitizers

Metal-containing photosensitizers

Ru(bpy)3Cl2 Ir(dFppy)3 100497


Non-metal-containing photosensitizers

5,10-Di(2-naphthyl)-5,10-dihydrophenazine 3,7-Di((1,1'-biphenyl)-4-yl)-10-(naphthalen-1-yl)-10H-phenoxazine purpurin 100500



Catalysts

Manganese-based catalysts

Entry CAT conc PS conc e-D conc Solvent lamdaexc irr time CO TON QY [%] further data link to experiment
1 100012 100010
2 100013 100010
3 100014 100010
4


Iron-based catalysts

Iron complexes: Known for the reduction of CO2 to H2 and CO [link to publication]

Fe(PP)Cl

Entry CAT conc PS conc e-D conc Solvent lamdaexc irr time CO TON QY [%] further data link to experiment
1 100005 100012 100010
2 100005 100013 100010
3 100005 100014 100010
4

Rhenium-based catalysts

Rhenium complexes are known to act as photocatalysts and electrocatalysts for reducing CO2 to CO.

Here an example DOI as reference [TMo14][Pro21] [EtF21]

Entry CAT conc PS conc e-D conc Solvent lamdaexc irr time CO TON QY [%] further data link to experiment
1 100006 100012 100010
2 100006 100013 100010
3 100006 100014 100010
4

Nickel-based catalysts

nickel;1,4,8,11-tetrazacyclotetradecane

Entry CAT conc PS conc e-D conc Solvent lamdaexc irr time CO TON QY [%] further data link to experiment
1 100007 100012 100010
2 100007 100013 100010
3 100007 100014 100010
4

Cobalt-based catalysts

Co(tpy)2

Entry CAT conc PS conc e-D conc Solvent lamdaexc irr time CO TON QY [%] further data link to experiment
1 100008 100012 100010
2 100008 100013 100010
3 100008 100014 100010
4


Combined Systems

Rhenium polypyridine complexes are known to act as photocatalysts and electrocatalysts for reducing CO2 to CO.289 A major problem with these photocatalysts is the lack of an extended absorption into the visible region. Therefore, they need to be supported by photosensitizers. The present approach is to fabricate supramolecular photocatalysts, similar to the photocatalytic H2 or O2 production systems. Supramolecular photocatalysts used in the reduction of CO2 act as both the light absorbing center and the catalytic center. Two distinct reaction mechanisms that use supramolecular photocatalysts for the reduction of CO2, are oxidative quenching (OQ) and reductive quenching (RQ).290 As shown in Fig. 56, for both mechanisms, the reduction of CO2 proceeds via the reduced form of the catalyst. Since the first supramolecular Ru–Ni complex used for the photochemical reduction of CO2 was reported by Kimura et al. in 1992,291 huge efforts had been devoted to the design of new bi- or multi-metallic analogues. Ishitani’s group have recently described the development of supramolecular photocatalysts for the photochemical reduction of CO2, 290 including Ru(II)–Re(I), Ru(II)–Ru(II), Ru(II)–Ni(II), Ru(II)–Co(III), Ir(III)–Re(I), Os(II)–Re(I), Pd(II)–Re(I), Zn(II)–Re(I), Fe(III)–Re(I), Co(II)–Re(I) and Cu(II)–Re(I) systems. Their chemical structures and photocatalytic CO2 reduction performance are presented in Fig. 57, 58 and Tables 9, 10. Therefore, in this section, we will mainly focus on the latest development of novel asymmetrical trinuclear supramolecular photocatalysts and their performance to supplement the recent review.290 Recently, Ishitani’s group synthesized two trinuclear supramolecular photocatalysts 319 and 320 (Fig. 59) containing three different metal centers Os(II)–Re(I)–Ru(II) for the first time316 via stepwise Mizoroki–Heck reactions. The energy transfer processes in these complexes were studied in detail. The key findings are: (1) highly efficient intramolecular energy transfer from an excited Re unit to an excited Ru unit was observed for both complexes, and the emission occurs mainly from excited Ru and Os units. (2) The faster energy transfer rate observed from the Re to the Ru unit, compared with from the Ru or Re to the Os unit, can be attributed to the different energy transfer mechanisms. For example, Furue et al. had reported that the intramolecular excited energy transfer in a Ru–Os dinuclear complex proceeds by a Fo¨rster mechanism,317 whereas the excited Re-Ru energy transfer proceeds via a Dexter mechanism.318 (3) In contrast to 319, the intramolecular excited Ru-Os energy transfer in 320 proceeded very slowly or did not occur, which can be attributed to the longer distance between the Ru and Os units in 320. Referring to supramolecular photocatalysts,290 dinuclear Ru–Re or Os–Re systems exhibit the best photocatalytic CO2 reduction performance reported to date for bimetallic systems. Inspired by this, two trinuclear complexes 319 and 320 were compared with their dinuclear Ru–Re and Os–Re analogues. As shown in Fig. 60a, both 319 and 320 can be used as supramolecular photocatalysts for the highly selective formation of CO. Importantly, both 319 and 320 exhibited superior catalytic ability and great durability in the CO2 reduction process. The TONs for 319 and 320. reached 3552 � 461 and 4347 � 421, respectively, after 35 h irradiation, which are higher than the summation of their parent dinuclear Ru–Re and Os–Re complexes. These two trinuclear complexes exhibit the highest TONCO for all reported photocatalytic reactions. The reason for this outstanding performance has been investigated by UV absorption measurements. As shown in Fig. 60b, upon irradiation at l 4 500 nm for 1 h, the spectrum of 319 showed a slight decrease in the band at ca. 420 to 500 nm. The spectral shape was maintained for 6 h. On the contrary, in the case of the Ru–Re analogue, the absorption band at 460 nm sharply decreased in intensity with continuous irradiation (Fig. 60c), which mainly reflects the decomposition of the Ru unit. The corresponding time courses of the absorbance changes at 460 nm for 319 and for dinuclear Ru–Re are shown in Fig. 60d. The change in the absorption intensity matched well with the time courses of photocatalytic CO formation for both catalysts (Fig. 60a). Therefore, this result indicated that the photocatalytic stability can be effectively improved by the introduction of the Os unit into the Ru–Re system. In summary, introduction of an additional photosensitising Os unit into Ru–Re systems to give trinuclear complexes 319 and 320 has two main advantages in comparison with the parent dinuclear complexes: (1) a wider range of visible light up to 730 nm can be strongly captured by the trinuclear complexes. (2) Photocatalytic durability of 319 and 320 is improved by 27% and 55%, respectively, compared with their parent dinuclear complexes.

Sacrificial electron donors

TEA TEOA BI(OH)H BIH BNAH 1-methylnaphthalene

-
Entry CAT PS e-D Solvent lamdaexc irr time CO TON Fara [%] H2 TON Fara [%] HCO2H TON QY [%] CH4 TON Fara [%] Ref

Additional information/Literature

[ECo20], [CEP20]

Literature

[TMo14] The Mechanism of Homogeneous CO2Reduction by Ni(cyclam): Product Selectivity, Concerted Proton–Electron Transfer and C–O Bond Cleavage. Jinshuai Song, Eric L. Klein, Frank Neese, Shengfa Ye, Inorganic Chemistry 2014, Vol. 53, Pages 7500-7507. DOI2: 10.1021/ic500829p
[Pro21] Photochemical reduction of carbon dioxide to formic acid. Robin Cauwenbergh, Shoubhik Das, Green Chemistry 2021, Vol. 23, Pages 2553-2574. DOI2: 10.1039/d0gc04040a
[ECo20] Electrochemical Conversion of CO 2 to CO by a Competent Fe I Intermediate Bearing a Schiff Base Ligand. Ruggero Bonetto, Roberto Altieri, Mirko Tagliapietra, Antonio Barbon, Marcella Bonchio, Marc Robert, Andrea Sartorel, ChemSusChem 2020, Vol. 13, Pages 4111-4120. DOI2: 10.1002/cssc.202001143