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Multi-phosphine-chelated iron-carbide clusters via redox-promoted ligand exchange on an inert hexa-iron-carbide carbonyl cluster, [Fe 6 (μ 6 -C)(μ 2 -CO) 4 (CO) 12 ] 2 .
- Source :
-
Chemical science [Chem Sci] 2024 Jun 24; Vol. 15 (29), pp. 11455-11471. Date of Electronic Publication: 2024 Jun 24 (Print Publication: 2024). - Publication Year :
- 2024
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Abstract
- We report the reactivity, structures and spectroscopic characterization of reactions of phosphine-based ligands (mono-, di- and tri-dentate) with iron-carbide carbonyl clusters. Historically, the archetype of this cluster class, namely [Fe <subscript>6</subscript> (μ <subscript>6</subscript> -C)(μ <subscript>2</subscript> -CO) <subscript>4</subscript> (CO) <subscript>12</subscript> ] <superscript>2-</superscript> , can be prepared on a gram-scale but is resistant to simple ligand substitution reactions. This limitation has precluded the relevance of iron-carbide clusters relating to organometallics, catalysis and the nitrogenase active site cluster. Herein, we aimed to derive a simple and reliable method to accomplish CO → L (where L = phosphine or other general ligands) substitution reactions without harsh reagents or multi-step synthetic strategies. Ultimately, our goal was ligand-based chelation of an Fe <subscript> n </subscript> (μ <subscript> n </subscript> -C) core to achieve more synthetic control over multi-iron-carbide motifs relevant to the nitrogenase active site. We report that the key intermediate is the PSEPT-non-conforming cluster [Fe <subscript>6</subscript> (μ <subscript>6</subscript> -C)(CO) <subscript>16</subscript> ] (2: 84 electrons), which can be generated in situ by the outer-sphere oxidation of [Fe <subscript>6</subscript> (μ <subscript>6</subscript> -C)(CO) <subscript>16</subscript> ] <superscript>2-</superscript> (1: closo , 86 electrons) with 2 equiv. of [Fc]PF <subscript>6</subscript> . The reaction of 2 with excess PPh <subscript>3</subscript> generates a singly substituted neutral cluster [Fe <subscript>5</subscript> (μ <subscript>5</subscript> -C)(CO) <subscript>14</subscript> PPh <subscript>3</subscript> ] (4), similar to the reported reactivity of the substitutionally active cluster [Fe <subscript>5</subscript> (μ <subscript>5</subscript> -C)(CO) <subscript>15</subscript> ] with monodentate phosphines (Cooke & Mays, 1990). In contrast, the reaction of 2 with flexible, bidentate phosphines (DPPE and DPPP) generates a wide range of unisolable products. However, the rigid bidentate phosphine bis(diphenylphosphino)benzene (bdpb) disproportionates the cluster into non-ligated Fe <subscript>3</subscript> -carbide anions paired with a bdpb-supported Fe(ii) cation, which co-crystallize in [Fe <subscript>3</subscript> (μ <subscript>3</subscript> -CH)(μ <subscript>3</subscript> -CO)(CO) <subscript>9</subscript> ] <subscript>2</subscript> [Fe(MeCN) <subscript>2</subscript> (bdpb) <subscript>2</subscript> ] (6). A successful reaction of 2 with the tripodal ligand Triphos generates the first multi-iron-chelated, authentic carbide cluster of the formula [Fe <subscript>4</subscript> (μ <subscript>4</subscript> -C)(κ3-Triphos)(CO) <subscript>10</subscript> ] (9). DFT analysis of the key (oxidized) intermediate 2 suggests that its (μ <subscript>6</subscript> -C)Fe <subscript>6</subscript> framework remains fully intact but is distorted into an axially compressed, 'ruffled' octahedron distinct from the parent closo cluster 1. Oxidation of the cluster in non-coordinating solvent allows for the isolation and crystallization of the CO-saturated, intact closo -analogue [Fe <subscript>6</subscript> (μ <subscript>6</subscript> -C)(CO) <subscript>17</subscript> ] (3), indicating that the intact (μ <subscript>6</subscript> -C)Fe <subscript>6</subscript> motif is retained during initial oxidation with [Fc]PF <subscript>6</subscript> . Overall, we demonstrate that redox modulation beneficially 'bends' Wade-Mingo's rules via the generation of electron-starved (non-PSEPT) intermediates, which are the key intermediates in promoting facile CO → L substitution reactions in iron-carbide-carbonyl clusters.<br />Competing Interests: There are no conflicts to declare.<br /> (This journal is © The Royal Society of Chemistry.)
Details
- Language :
- English
- ISSN :
- 2041-6520
- Volume :
- 15
- Issue :
- 29
- Database :
- MEDLINE
- Journal :
- Chemical science
- Publication Type :
- Academic Journal
- Accession number :
- 39055015
- Full Text :
- https://doi.org/10.1039/d4sc01370k