Homogeneous Systems Containing Earth‐Abundant Metal Complexes for Photoactivated CO<sub>2</sub> Reduction: Recent Advances

Bizzarri, Claudia

doi:10.1002/ejoc.202200185

Cited by 21 publications

(12 citation statements)

References 103 publications

(99 reference statements)

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“…These studies require the combination of a molecular catalyst (Cat) with a light-harvesting photosensitizer (PS) and an electron donor (ED). 12,29,30 Under irradiation conditions, excitation of the PS is followed by reductive electron transfer quenching of the excited state PS* by the ED, leading to the formation of the reduced PS − species. This latter then undergoes electron transfer to the catalyst, either in its pristine (Cat) or one-electron reduced (Cat − ) form (Fig.…”

Section: Assessment Of Molecular Catalystsmentioning

confidence: 99%

Bioinspired motifs in proton and CO₂ reduction with 3d-metal polypyridine complexes

Droghetti,

Amati,

Ruggi

et al. 2024

Chem. Commun.

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Section: Assessment Of Molecular Catalystsmentioning

confidence: 99%

Bioinspired motifs in proton and CO₂ reduction with 3d-metal polypyridine complexes

Droghetti,

Amati,

Ruggi

et al. 2024

Chem. Commun.

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Section: Introductionmentioning

confidence: 99%

“…There is an ongoing demand for ever stronger photooxidants and photoreductants, especially with the aim to develop effective photoredox catalysts for intricate processes like small-molecule activation (e.g., CO 2 , NO 3 – , and N 2 ). , Understanding the mechanisms and factors that influence the redox properties of photoredox catalysts is vital to establishing design principles for adjusting the reactivity while meeting the demands for greener synthetic protocols. , Modifying the metal center, , counterions, and ligands , are known mechanisms for tuning the reduction potentials of transition metal complexes. For this, it is important to understand that the four electron transfer events of the oxidative and reductive quenching cycles (shown in Figure ) can be characterized as formally metal- ( D ox → S 0 and T 1 → D red ) and ligand-centered ( S 0 → D red and D ox → T 1 ) redox processes. , Particularly, in the latter, the intrinsic properties of the redox-active ligands profoundly impact the thermodynamics of the electron transfer event.…”

Section: Introductionmentioning

confidence: 99%

Fusion Position-Dependent Aromatic Transitions of Ligand Backbone Rings for Controlling the Redox Energetics of Photoredox Catalysts

Girnt,

Molina-Aguirre,

Gomez Bustos

et al. 2024

Inorg. Chem.

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To reveal, quantify, and rationalize the effect of backbone π-extension on ligand redox activity, we studied the ground-and excited-state reduction potentials of eight ruthenium photoredox catalysts with the formula Ru(ppy) 2 L (L is the redox-active ligand of the bipyridine family) using density functional theory. Our research underlines the profound importance of the fusion position of backbone aromatic C 6 rings on the redox activity of ligands in transition metal photoredox catalysts. Namely, certain fusion positions lead to the dearomatization of C 6 rings in ligand-centered electron transfer events, resulting in a thermodynamic penalty equivalent to a half-volt negative shift in the reduction potential. Contrarily, the extent of backbone delocalization shows a minimal impact on redox energetics, which can be explained by the charge concentration at the nitrogen contact atoms in ligand-centered reductions. Grounded in Caulton's conceptual framework, we reaffirm the predictive potency of Lewis structures in ligand-centered redox energetics with qualitative and quantitative data. Our hypothesis regarding the effect of backbone ring dearomatization on redox energetics is further corroborated using magnetic and structure-based aromaticity indicators. Highlighting fusion-dependent dearomatization as a determining factor of ligand-centered electron transfer energetics, our findings hold implications for molecular-level design in advanced electroactive materials and catalysts.

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“…Catalytic reactions utilizing earth-abundant metals as catalysts are crucial in terms of the expansion of metal resources. As 3d metals, such as Cu and Fe, are more abundant than central metal ions of well-known efficient catalysts, such as Ru, Rh, and Pd (4d metals) and Pt (5d metal), the utilization of 3d metal elements as catalysts is attracting widespread research attention . However, 3d metals tend to lose their original structure owing to oxidation and/or ligand dissociation, which are generally the main reasons for their efficient catalytic functions being difficult.…”

Section: Introductionmentioning

confidence: 99%

Photocatalytic CO₂ Reduction Using Mixed Catalytic Systems Comprising an Iron Cation with Bulky Phenanthroline Ligands

Takeda,

Irimajiri,

Mizutani

et al. 2024

Inorg. Chem.

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This study reports on efficient photocatalytic CO 2 reduction reactions using mixed catalytic systems of an Fe ion source and various 1,10-phenanthroline derivatives (R 1 R 2 p) as ligands in the presence of triethanolamine (TEOA). As the relatively bulky substituents at positions 2 and 9 of R 1 R 2 p weakened the ability to coordinate to the Fe ion, the Fe ion formed TEOA complexes. The free R 1 R 2 p accepted an electron from the reduced photosensitizer through proton-coupled electron transfer (PCET) using protons of TEOA dissolved in a CH 3 CN solution in a CO 2 atmosphere as the initial step of the catalytic cycle. Although the mixed system of the nonsubstituted 1,10-phenanthroline generates a stable tris(phenanthroline)−Fe(II) complex in solution, this complex could not function as a CO 2 reduction catalyst. The mechanism in which R 1 R 2 p interacts with the Fe ion after PCET was proposed for this efficient photocatalytic CO 2 reduction. The proposed photocatalytic system using the 2,9-di-sec-butyl-phenanthroline ligand could produce CO with high efficiency (quantum yield of 8.2%) combined with a dinuclear Cu(I) complex as a photosensitizer.

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Homogeneous Systems Containing Earth‐Abundant Metal Complexes for Photoactivated CO₂ Reduction: Recent Advances

Cited by 21 publications

References 103 publications

Bioinspired motifs in proton and CO₂ reduction with 3d-metal polypyridine complexes

Bioinspired motifs in proton and CO₂ reduction with 3d-metal polypyridine complexes

Fusion Position-Dependent Aromatic Transitions of Ligand Backbone Rings for Controlling the Redox Energetics of Photoredox Catalysts

Photocatalytic CO₂ Reduction Using Mixed Catalytic Systems Comprising an Iron Cation with Bulky Phenanthroline Ligands

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Homogeneous Systems Containing Earth‐Abundant Metal Complexes for Photoactivated CO2 Reduction: Recent Advances

Cited by 21 publications

References 103 publications

Bioinspired motifs in proton and CO2 reduction with 3d-metal polypyridine complexes

Bioinspired motifs in proton and CO2 reduction with 3d-metal polypyridine complexes

Fusion Position-Dependent Aromatic Transitions of Ligand Backbone Rings for Controlling the Redox Energetics of Photoredox Catalysts

Photocatalytic CO2 Reduction Using Mixed Catalytic Systems Comprising an Iron Cation with Bulky Phenanthroline Ligands

Contact Info

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About

Homogeneous Systems Containing Earth‐Abundant Metal Complexes for Photoactivated CO₂ Reduction: Recent Advances

Bioinspired motifs in proton and CO₂ reduction with 3d-metal polypyridine complexes

Bioinspired motifs in proton and CO₂ reduction with 3d-metal polypyridine complexes

Photocatalytic CO₂ Reduction Using Mixed Catalytic Systems Comprising an Iron Cation with Bulky Phenanthroline Ligands