Synthesis of Well‐Defined Bicapped Octahedral Iron Clusters [(trenL)2Fe8(PMe2Ph)2]n (n=0, −1)

Sánchez, Raúl Hernández; Willis, Alexander M.; Zheng, Shao‐Liang; Betley, Theodore A.

doi:10.1002/ange.201505671

Cited by 8 publications

(1 citation statement)

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“…the identity of the Fe precursor and the presence or absence of additional phosphine ligands) 36,37 and that 8-Fe clusters could be accommodated by expanding the size of the ligand cavity and introducing an additional amine donor. 38 In addition, reactive trimetallic clusters have been prepared using a rigid tris(diketiminate) scaffold developed by Murray et al [39][40][41][42] and Agapie et al have employed a 1,3,5-triarylbenzene substituted with three dipyridyl alkoxide groups as a framework to selectively construct, for example, Mn3O4M (M = Ca 2+ , Ln 3+ , etc.) cubanes as models for the oxygen-evolving complex in photosystem II.…”

Section: Introductionmentioning

confidence: 99%

Selective Synthesis of Site-Differentiated Fe₄S₄ and Fe₆S₆ Clusters

McSkimming

Suess

2018

Inorg. Chem.

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Obtaining rational control over the structure and nuclearity of metalloclusters is an ongoing challenge in synthetic Fe-S cluster chemistry. We report a new family of tridentate imidazolin-2-imine ligands L(NIm R)3 that can bind [Fe4S4] 2+ or [Fe6S6] 3+ clusters, depending on the steric profile of the ligand and the reaction stoichiometry. A high-yielding synthetic route to L(NIm R)3 ligands (where R is the imidazolyl N substituents) from trianiline and 2-chloroimidazolium precursors is described. For L(NIm Me)3 (tris(1,3,5-(3-(N,N-dimethyl-4,5-diphenylimidazolin-2-imino)phenylmethyl))benzene), metalation with 1 equiv. [Ph4P]2[Fe4S4Cl4] and 3 equiv. NaBPh4 furnishes a mixture of products, but adjusting the stoichiometry to 1.5 equiv. [Ph4P]2[Fe4S4Cl4] provides (L(NIm Me)3)Fe6S6Cl6 in high yield. Formation of an [Fe6S6] 3+ cluster using L(NIm Tol)3 (tris(1,3,5-(3-(N,N-bis(4-methylphenyl)-4,5diphenylimidazolin-2-imino)phenylmethyl))benzene) is not observed; instead, the [Fe4S4] 2+ cluster [L(NIm Tol)3)(Fe4S4Cl)][BPh4] is cleanly generated when 1 equiv. [Ph4P]2[Fe4S4Cl4] is employed. The selectivity for cluster nuclearity is rationalized by the orientation of the imidazolyl rings whereby long N-imidazolyl substituents preclude formation of [Fe6S6] 3+ clusters but not [Fe4S4] 2+ clusters. Thus, the

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Section: Introductionmentioning

confidence: 99%

Selective Synthesis of Site-Differentiated Fe₄S₄ and Fe₆S₆ Clusters

McSkimming

Suess

2018

Inorg. Chem.

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Alkene Hydrogenations by Soluble Iron Nanocluster Catalysts

et al. 2017

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The replacement of noble metal technologies and the realization of new reactivities with earth-abundant metals is at the heart of sustainable synthesis.Alkene hydrogenations have so far been most effectively performed by noble metal catalysts. This study reports an iron-catalyzedh ydrogenation protocol for tri-and tetra-substituted alkenes of unprecedented activity and scope under mild conditions (1-4 bar H 2 ,2 08 8C). Instructive snapshots at the interface of homogeneous and heterogeneous iron catalysis were recorded by the isolation of novel Fe nanocluster architectures that act as catalyst reservoirs and soluble seeds of particle growth.

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Synthesis and Reactivity of an Early‐Transition‐Metal Alkynyl Cubane Mn₄C₄ Cluster

et al. 2019

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While the coordination chemistry of monometallic complexes and the surface properties of extended metal particles are well understood, the control of metal nanocluster formation has remained challenging. The isolation of discrete metal clusters provides an especially rare snapshot at the nanoscale of cluster growth. The synthesis and full characterization of the first early-transition-metal alkynyl cubane and the first m 3 -alkynyl Mn 3 motif are reported. Scheme 1. Transition-metal clusters:S carcity of CO-free alkynyl metal clusters other than with coinage metals.Scheme 2. The m 3 -X-M motif in planar hydridomanganese and 3D alkynyl-manganese clusters (R = SiMe 3 ).Supportinginformation and the ORCID identification number for one of the authors of this article can be found under: https://doi.

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Synthesis of Well‐Defined Bicapped Octahedral Iron Clusters [(^trenL)₂Fe₈(PMe₂Ph)₂]ⁿ (n=0, −1)

Cited by 8 publications

References 62 publications

Selective Synthesis of Site-Differentiated Fe₄S₄ and Fe₆S₆ Clusters

Selective Synthesis of Site-Differentiated Fe₄S₄ and Fe₆S₆ Clusters

Alkene Hydrogenations by Soluble Iron Nanocluster Catalysts

Synthesis and Reactivity of an Early‐Transition‐Metal Alkynyl Cubane Mn₄C₄ Cluster

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Synthesis of Well‐Defined Bicapped Octahedral Iron Clusters [(trenL)2Fe8(PMe2Ph)2]n (n=0, −1)

Cited by 8 publications

References 62 publications

Selective Synthesis of Site-Differentiated Fe4S4 and Fe6S6 Clusters

Selective Synthesis of Site-Differentiated Fe4S4 and Fe6S6 Clusters

Alkene Hydrogenations by Soluble Iron Nanocluster Catalysts

Synthesis and Reactivity of an Early‐Transition‐Metal Alkynyl Cubane Mn4C4 Cluster

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Synthesis of Well‐Defined Bicapped Octahedral Iron Clusters [(^trenL)₂Fe₈(PMe₂Ph)₂]ⁿ (n=0, −1)

Selective Synthesis of Site-Differentiated Fe₄S₄ and Fe₆S₆ Clusters

Selective Synthesis of Site-Differentiated Fe₄S₄ and Fe₆S₆ Clusters

Synthesis and Reactivity of an Early‐Transition‐Metal Alkynyl Cubane Mn₄C₄ Cluster