Iron(0) tricarbonyl η<sup>4</sup>-1-azadiene complexes and their catalytic performance in the hydroboration of ketones, aldehydes and aldimines<i>via</i>a non-iron hydride pathway

Luo, Jiabin; Cui, Chuanguo; Xiao, Zhiyin; Zhong, Wei; Lü, Chunxin; Jiang, Xiujuan; Li, Xueming; Liu, Xiaoming

doi:10.1039/d2dt01673g

Cited by 4 publications

(3 citation statements)

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“…The bond distance of C12-C13 in 2 is 1.421( 5) Å (Table 2 and Figure 4), falling in the range between a single bond and a double bond, which is consistent with bond elongation caused by η-bonding between a metal center and a C=C bond. [44][45][46][47] For example, in iron(0) tricarbonyl η 4 -1-azadiene complexes ([Fe 0 (CO) 3 (η 4 -N(R 1 ) = C-C=C(R 2 )]), the distance of C=C bond is ca. 1.41 Å.…”

Section: Crystal Structures Of the Iron Carbonyl Complexesmentioning

confidence: 99%

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The reaction of nonacarbonyldiiron with 8‐alkynyloxyquinolines: Alkynyl activation, cyclization via C‐N bond formation, and C‐H bond cleavage

Luo,

Yu,

Chu

et al. 2024

Applied Organom Chemis

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In this work, the reactions of nonacarbonyldiiron with 8‐alkynyloxyquinoline ligands (L1‐L3) and their resultant iron carbonyl complexes (1a, 1b, 2, and 3) are described. The complexes including the ligands were fully characterized by using a variety of spectroscopic techniques. The four complexes were also crystallographically determined. In the reactions, the quinoline N atom underwent cyclization to form a quinolinium skeleton while the C‐H bond of the quinoline at position 2 or the substituted methyl group was cleaved to form Fe‐C bond(s). Meanwhile, the alkynyl triple bond was reduced to a single bond (1a) or double bonds (1b, 2, and 3) to further coordinate the iron in σ‐bonds or η‐bonds. Particularly, pathways of hydrogenation (1a and 2) and/or dehydrogenation (1b and 3) were accompanied by the reactions. Moreover, the oxidation states of the iron centers in these complexes were identified through analyses of their bond formation, FTIR and NMR spectroscopic signals (1H NMR and DEPT‐135) in combination with their diamagnetic nature, that is, iron (0) for 2 and iron (I) for the rest of the diiron complexes.

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Section: Crystal Structures Of the Iron Carbonyl Complexesmentioning

confidence: 99%

“…1.41 Å. 47 Therefore, the coordination of the bond C12-C13 to the iron center is a η 2 -bonding between a vinyl bond and a metal center. Its activity in NMR and the five-coordinated nature imply that the iron center is Fe(0) in complex 2.…”

Section: Crystal Structures Of the Iron Carbonyl Complexesmentioning

confidence: 99%

The reaction of nonacarbonyldiiron with 8‐alkynyloxyquinolines: Alkynyl activation, cyclization via C‐N bond formation, and C‐H bond cleavage

Luo,

Yu,

Chu

et al. 2024

Applied Organom Chemis

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“…In this scenario, iron-based catalysts have garnered significant attention owing to their promising catalytic activity, ready availability, and cost-effectiveness. Although the hydroboration of alkenes and alkynes using iron catalysts has been well established in recent years, reports particularly focusing on iron-catalyzed hydroboration of ketones are scarce in the literature. For instance, in 2017, Findlater and Tamang developed a novel approach for the hydroboration of aldehydes and ketones by utilizing Fe(acac) 3 as a catalyst, along with an additive NaHBEt 3 , to generate an active Fe–H intermediate species responsible for the catalytic activity.…”

Section: Introductionmentioning

confidence: 99%

Air-Stable Iron(III) Salen Complexes for Selective Hydroboration of Ketones and Unactivated Imines without Base Activation

Latha,

2024

J. Org. Chem.

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Herein, we designed and synthesized a series of airstable, cost-effective, and readily synthesizable iron(III) salen complexes (Fe-1 and Fe-2) for facilitating the selective hydroboration of ketones and unactivated imines with pinacolborane in the absence of any additive. These catalyst systems exhibited good yields, chemoselectivity, high atom economy, and a broad substrate scope under mild reaction conditions with a minimal catalyst loading of 0.2 mol %. The catalytic efficiency of Fe-1 has been demonstrated through the hydroboration of diverse aromatic, aliphatic, and heterocyclic ketones and imines with a turnover number of up to 1000, highlighting its broad substrate scope. Ketones are chemoselectively hydroborated over other functional groups such as imines, alkenes, esters, nitriles, acids, and alcohols. Besides, the synthetic utility of this strategy has also been showcased by the construction of a natural chiral monoterpenoid carveol. This protocol can be readily scaled up for gram-scale synthesis of alcohols, which underscores the potential industrial applicability of our catalyst system in the synthesis of secondary alcohols on a larger scale.

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Multisite Amino‐Allylidene Ligands from Thermal CO Elimination in Diiron Complexes and Catalytic Activity in Hydroboration Reactions

Zappelli,

Taglieri,

Schoch

et al. 2024

ChemCatChem

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The new diiron(I) complexes [Fe2Cp2(μ‐CO){μ‐k3C,kN‐C(R1)C(R2)C(CN)NMe(R)}], 3a‐o (R = alkyl or 4‐C6H4OMe; R1 = alkyl, aryl, ferrocenyl (Fc), thiophenyl, CO2Me or SiMe3; R2 = H, Me or CO2Me) were synthesized in moderate to high yields from the thermal decarbonylation of the bis‐carbonyl precursors 2a‐o, and were structurally characterized by IR and NMR spectroscopy, and single crystal X‐ray diffraction in four cases. Electrochemical behavior of one complex was also investigated. Complexes 3a‐o comprise a highly functionalized, multisite amino‐(cyano)allylidene ligand, including metal coordination of a tertiary amine group. Selected complexes displayed negligible to moderate catalytic activity in CO2/propylene oxide coupling, working under ambient conditions. Additionally, they were investigated as catalysts for the conversion of benzaldehyde to the corresponding borate ester 6a, using pinacolborane (HBpin) as the borylating agent. Most complexes achieved good conversions at room temperature with 1% catalyst loading, and data highlight the significant influence of the multisite ligand substituents on the catalytic performance. Notably, complex 3m (featuring R = 4‐methoxyphenyl, R1 = Fc, R2 = H) displayed the highest activity and effectively catalyzed the hydroboration of various aldehydes and ketones. A plausible mechanistic cycle involves metal coordination of the carbonyl substrate, its activation being possibly facilitated by intramolecular interactions.

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Iron(0) tricarbonyl η⁴-1-azadiene complexes and their catalytic performance in the hydroboration of ketones, aldehydes and aldiminesviaa non-iron hydride pathway

Abstract: Iron(0) tricarbonyl η4-1-azadiene complexes catalyse the hydroboration of aldehydes, ketones, and aldimines with pinacolborane as a hydride source via an intermolecular hydride transfer pathway rather than an iron-hydride intermediate.

Cited by 4 publications

References 57 publications

The reaction of nonacarbonyldiiron with 8‐alkynyloxyquinolines: Alkynyl activation, cyclization via C‐N bond formation, and C‐H bond cleavage

The reaction of nonacarbonyldiiron with 8‐alkynyloxyquinolines: Alkynyl activation, cyclization via C‐N bond formation, and C‐H bond cleavage

Air-Stable Iron(III) Salen Complexes for Selective Hydroboration of Ketones and Unactivated Imines without Base Activation

Multisite Amino‐Allylidene Ligands from Thermal CO Elimination in Diiron Complexes and Catalytic Activity in Hydroboration Reactions

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Iron(0) tricarbonyl η4-1-azadiene complexes and their catalytic performance in the hydroboration of ketones, aldehydes and aldiminesviaa non-iron hydride pathway

Abstract: Iron(0) tricarbonyl η4-1-azadiene complexes catalyse the hydroboration of aldehydes, ketones, and aldimines with pinacolborane as a hydride source via an intermolecular hydride transfer pathway rather than an iron-hydride intermediate.

Cited by 4 publications

References 57 publications

The reaction of nonacarbonyldiiron with 8‐alkynyloxyquinolines: Alkynyl activation, cyclization via C‐N bond formation, and C‐H bond cleavage

The reaction of nonacarbonyldiiron with 8‐alkynyloxyquinolines: Alkynyl activation, cyclization via C‐N bond formation, and C‐H bond cleavage

Air-Stable Iron(III) Salen Complexes for Selective Hydroboration of Ketones and Unactivated Imines without Base Activation

Multisite Amino‐Allylidene Ligands from Thermal CO Elimination in Diiron Complexes and Catalytic Activity in Hydroboration Reactions

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Iron(0) tricarbonyl η⁴-1-azadiene complexes and their catalytic performance in the hydroboration of ketones, aldehydes and aldiminesviaa non-iron hydride pathway