Two Exceptional Homoleptic Iron(IV) Tetraalkyl Complexes

Casitas, Alicia; Rees, Julian A.; Goddard, Richard; Bill, Eckhard; DeBeer, Serena; Fürstner, Alois

doi:10.1002/anie.201612299

Cited by 57 publications

(42 citation statements)

References 77 publications

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Section: Resultsmentioning

confidence: 99%

“…Our group has recently shown that the reactiono fF eX n (n = 2, 3) with cyclohexylmagnesium chloride is ah ighly involved process,i nw hichd isproportionation of the transiento rganoiron species and/or allylic CÀHa ctivation processes will eventually interfere. [31,34] It was for this reasont hat this particularn ucleophile had been chosen for reaction optimization. The fact that the cyclohexyl group was transferred almost quantitatively augured well for the scope of the reactionw ith regard to the nucleophilic partner.I ndeed, ar ange of (functionalized) alkyl-Grignardr eagents performed nicely ( Table 2);e ven the isopropyl group was successfully transferred, although cross-coupling reactions of secondary alkyl donors in general are often plaguedb yi somerization to the linear isomersv ia rapid MÀH elimination/re-addition (entry 4); [35] of the primary Grignard reagents investigated, only TMSCH 2 MgCl failed to participate in the cascade, most likely for the b-silicon effect that is thought to stabilize the transiento rganoiron species.…”

Section: Iron-catalyzedr Eaction Cascades Of Enynes With Heteroatom Tmentioning

confidence: 99%

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Iron‐ or Palladium‐Catalyzed Reaction Cascades Merging Cycloisomerization and Cross‐Coupling Chemistry

Gomes

Echeverria

Fürstner

2018

Chemistry A European J

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A conceptually novel reaction cascade is presented, which allows readily available enynes to be converted into functionalized 1,3-dienes comprising a stereodefined tetrasubstituted alkene unit; such compounds are difficult to make by conventional means. The overall transformation is thought to commence with formation of a metallacyclic intermediate that evolves via cleavage of an unstrained C-X bond in its backbone. This non-canonical cycloisomerization process is followed by a cross-coupling step, such that reductive C-C bond formation regenerates the necessary low-valent metal fragment and hence closes an intricate catalytic cycle. The cascade entails the formation of two new C-C bonds at the expense of the constitutional C-X entity of the substrate: importantly, the extruded group X must not be a heteroelement (X=O, NR), since activated β-C-C bonds can also be broken. This concern was reduced to practice in two largely complementary formats: one procedure relies on the use of alkyl-Grignard reagents in combination with catalytic amounts of Fe(acac) whereas the second method amalgamates cycloisomerization with Suzuki coupling by recourse to arylboronic acids and phosphine-ligated palladium catalysts.

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Section: Resultsmentioning

confidence: 99%

Section: Iron-catalyzedr Eaction Cascades Of Enynes With Heteroatom Tmentioning

confidence: 99%

Iron‐ or Palladium‐Catalyzed Reaction Cascades Merging Cycloisomerization and Cross‐Coupling Chemistry

Gomes

Echeverria

Fürstner

2018

Chemistry A European J

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“…[Fe(1‐norbornyl) 4 ], und [Co(1‐norbornyl) 4 ], wurden von Theopold und Tennent in den 1970er und 1980er Jahren beschrieben. Das Interesse an dieser Verbindungsklasse wurde kürzlich durch die Publikation des ersten Nickel(IV)‐Tetraalkylkomplexes [2d] und weiterer Eisen(IV)‐Komplexe [FeR 4 ] (R=Cyclohexyl, 2‐Adamantyl) wiederbelebt. Eine theoretische Studie von Power und Nagase legt nahe, dass diese Verbindungen maßgeblich durch London‐Dispersionskräfte stabilisiert werden …”

Section: Figureunclassified

Oxidative P‐P‐Bindungsaddition an Cobalt(−I): Bildung eines Low‐spin‐Cobalt(III)‐Phosphanidokomplexes

Coburger

Demeshko²,

Rödl

et al. 2017

Angewandte Chemie

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Die oxidative P‐P‐Bindungsaddition eines ortho‐Carboran‐substituierten 1,2‐Diphosphetans an Cobalt(−I) in [K(thf)0.2][Co(η4‐cod)2)] (cod=1,5‐Cycloctadien) ermöglichte die Darstellung des ersten homoleptischen Cobalt(III)‐Phosphanidokomplexes [K(thf)4][Co{1,2‐(PtBu)2C2B10H12}2] (1). Diese Verbindung ist ein seltenes Beispiel eines verzerrt tetraedrisch koordinierten 3d6‐Komplexes mit einem Low‐spin‐Grundzustand. Magnetische Messungen ergaben, dass 1 zwischen 2 und 270 K im Festkörper und bei 298 K in einer [D8]THF‐Lösung diamagnetisch ist. Dichtefunktionalrechnungen zeigten, dass der diamagnetische Grundzustand durch die starken σ‐Donor‐ und die moderaten π‐Donoreigenschaften der Bisphosphanidoliganden verursacht wird.

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“…The reason for this is twofold; first, the synthesis of adamantyl anions, specifically lithium and Grignard compounds, is fraught with highly erratic yields and side reactions, and reliable zinc chemistry has only recently been developed. [7b], [7c] Second, homoleptic metal adamantyl complexes have proven to be extremely insoluble, leading to difficulty in characterization. As such, metal complexes of the (unsupported) adamantyl group are very rare, and structurally characterized examples of 2‐adamantyl transition metal complexes have been, until very recently, non‐existent.…”

Section: Introductionmentioning

confidence: 99%

“…In 1980, Bochmann, Wilkinson, and Young attempted the synthesis of the first platinum adamantyl complex. [8c] This attempt was unsuccessful, yielding only biadamantyl as the final product. Here we present the first platinum 2‐adamantyl complexes to be isolated and characterized, namely [(COD)Pt(2‐Ad)Cl] ( 1 ), [(dppe)Pt(2‐Ad)Cl] ( 2 ), [(COD)Pt(2‐Ad)Me] ( 3 ), and [(dppe)Pt(2‐Ad)Me] ( 4 ) {COD = 1,5‐cyclooctadiene, dppe = 1,2‐bis(diphenylphosphino)ethane, Ad = adamantyl}.…”

Section: Introductionmentioning

confidence: 99%

2‐Adamantyl Complexes of Platinum

et al. 2019

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Dedicated to the memory of Paul von Ragué Schleyer, who made modern adamantyl chemistry possible.Abstract: The first adamantyl platinum complexes were isolated and characterized, namely [(COD)Pt(2-Ad)Cl], [(dppe)Pt(2-Ad)Cl], [(COD)Pt(2-Ad)Me] and, [(dppe)Pt(2-Ad)Me] {COD = 1,5cyclooctadiene, dppe = 1,2-bis(diphenylphosphino)ethane, Ad = adamantyl}. These complexes show considerable stability, including resistance to heating to 125°C in solution for several days. It is therefore concluded that previously existing road Adamantane, the simplest diamondoid molecule, has great potential for use in advanced materials, [1] drug development, [2] and ligands for organometallic catalysis. [3] Due to adamantane's innate chemical stability, the synthetic tool kit for the functionalization of the adamantyl group is still quite limited, in contrast to the situation for other alkyls. The exceptional donating ability of the adamantyl group at both the 1-adamantyl (bridgehead) and 2-adamantyl (bridge) positions makes transformations that involve carbocations rather straightforward. Conversely, many transformations involving carbanions, which are routine for other alkyls, are very difficult for adamantyls. [4] Arguably, efficient future procedures for functionalization of adamantane will be transition metal mediated, in particular for the bridge position, which in comparison to the bridgehead position, is much less accessible through radical pathways. [5] Despite substantial initial interest in adamantane within the organometallic community, largely due to adamantane's resistance to -elimination, progress in adamantyl metal chemistry over the last several decades has been very slow. [6] The reason for this is twofold; first, the synthesis of adamantyl anions, specifically lithium and Grignard compounds, is fraught with highly erratic yields and side reactions, [7] and reliable zinc chemistry has only recently been developed. [7b,7c] Second, homoleptic metal adamantyl complexes [8] have proven to be extremely insoluble, [a]

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Two Exceptional Homoleptic Iron(IV) Tetraalkyl Complexes

Cited by 57 publications

References 77 publications

Iron‐ or Palladium‐Catalyzed Reaction Cascades Merging Cycloisomerization and Cross‐Coupling Chemistry

Iron‐ or Palladium‐Catalyzed Reaction Cascades Merging Cycloisomerization and Cross‐Coupling Chemistry

Oxidative P‐P‐Bindungsaddition an Cobalt(−I): Bildung eines Low‐spin‐Cobalt(III)‐Phosphanidokomplexes

2‐Adamantyl Complexes of Platinum

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