Lewis acid promoted dehydration of amides to nitriles catalyzed by [PSiP]‐pincer iron hydrides

Chang, Guoliang; Li, Xiaoyan; Zhang, Peng; Yang, Wenjing; Li, Kai; Wang, Yajie; Sun, Hongjian; Fuhr, Olaf; Fenske, Dieter

doi:10.1002/aoc.5466

Cited by 17 publications

(10 citation statements)

References 40 publications

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“…The 1 H NMR spectrum of 6a showed a singlet in the high-field region at −17.7 ppm assignable to Fe–H, two sets of signals corresponding to the inequivalent Mes groups, and four multiplets assignable to the pyridyl ligand, in addition to a singlet of the Cp* ligand. The signal corresponding to the hydride on the iron center was shifted to a higher magnetic field relative to those of Cp*(OC)(L)FeH (L = CO and PMe 3 , −11 to −15 ppm), Cp*(OC)Fe(SiR 3 ) 2 H (−11 to −14 ppm), , and Cp*Fe(η 2 -H-ER 3 ) (E = Si and Ge, −12 to −14 ppm) and was comparable to that reported for Fe(diphosphine)(PR 3 ) 2 (SiR 3 )H (−14 to −19 ppm). , The IR spectrum showed one intense absorption band at 1918 cm –1 assignable to νCO. The absorption band was comparable to that of Cp*(OC)Fe(LB)(η 1 -aryl) (1903–1913 cm –1 , LB: Lewis base) …”

Section: Results and Discussionmentioning

confidence: 77%

Syntheses and Structures of Gallyliron Complexes with Pyridine Ligands and Their Reactions with Methyl Acrylate

et al. 2021

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Reactions of gallyliron complexes Cp*(OC)2FeGaR2 (R = Cl (1), Mes (2); Cp*, η5-C5Me5; Mes, 2,4,6-Me3C6H2) with pyridine in C6D6 afforded pyridine-stabilized gallyl complexes Cp*(OC)2Fe{GaR2(py)} (R = Cl (3), Mes (5a); py, pyridine). Photoirradiation of dichlorogallyl complex 3 in the presence of excess pyridine in benzene proceeded via the substitution of a CO ligand with another pyridine to give Cp*(OC)(py)Fe{GaCl2(py)} (4). However, photoirradiation of dimesitylgallyl complex 2 in the presence of excess pyridine gave gallane(pyridyl)iron complex Cp*(OC)Fe{(η1-HGaMes2)(η1-2-C5H4N)} (6a) via CO elimination and oxidative addition of the C–H bond at the 2-position of the gallium-coordinated pyridine. X-ray crystal structure analysis of 6a revealed the formation of a 3-center-2-electron (3c2e) bond in the Fe–H–GaMes2 fragment. Reaction of 4 with methyl acrylate in toluene at 50 °C resulted in substitution of the pyridine ligand on the iron atom with the C=C bond, giving Cp*(OC)(η2-CH2=CHCO2Me)Fe{GaCl2(py)} (7). In contrast, the reaction of 6a with methyl acrylate in toluene at 100 °C afforded vinyliron complex Cp*(OC)2Fe(CH=CH2) (8) and 4-membered Ga2O2 cyclic gallane compound [Mes2GaOMe]2 (9) via cleavage of the Fe–Ga, C–O, and C–C bonds.

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Section: Results and Discussionmentioning

confidence: 77%

Syntheses and Structures of Gallyliron Complexes with Pyridine Ligands and Their Reactions with Methyl Acrylate

et al. 2021

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“…表 2 芳香族酰胺脱水制备腈的4种催化体系范围为67%~92%. 随后, Li等 [169] 发现在PSiP配位的甲硅烷基氢化铁络合物催化体系中, 添加Lewis酸可以有效地促进催化活性, 降低反应温度, 反应条件更温和.…”

Section: 脱氢氧化生成腈unclassified

“…Figure26 Fe or Co complexes catalyzed dehydration of primary amides to nitriles with (EtO) 3 SiH[167][168][169][170] (color online).…”

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confidence: 99%

Progress in synthetic strategy and industrial preparation of aliphatic nitriles

Wang

Ding

et al. 2020

Sci. Sin.-Chim

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As important chemical raw materials and intermediates, aliphatic nitriles are widely used in the field of materials and medicine synthesis. In this review, we summarized the research progress in synthetic strategy, including the oxidative cyanation of alkanes, alkenes, aldehydes and amines, direct cyanation of alkanes, haloalkanes and alkenes with cyanogen reagents, and the dehydrative cyanation of amides, carboxylic acids (esters) and aldehyde oximes. Meanwhile, the industrial preparation progress of aliphatic nitriles and the bottleneck problems therein were introduced taking acrylonitrile, adiponitrile and acetonitrile as typical examples. The future development on the synthetic strategy and industrial preparation of aliphatic nitriles was also prospected.

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“…This is similar to hydrido iron(II) catalyst. 17 Recently, we reported that the classical [PSiP]-pincer iron hydride (2-Ph 2 PC 6 H 4 ) 2 -MeSiFe(H)(PMe 3 ) 2 was an efficient catalyst to dehydration of primary amides with the assistance of Lewis acid at 40 °C for 40 h. 18 On the basis of the above research, we attempt to design novel [PSiP] pincer ligands to synthesize [PSiP] pincer iron hydrids, even iron nitrogen complexes, and to explore the catalytic activity of these complexes for dehydration of primary amides. Recently, we reported that the N-heterocyclic σ-silyl [PSiP] pincer ligand 1 could stabilize iron hydride 2 (Scheme 1).…”

Section: ■ Introductionmentioning

confidence: 99%

“…This is similar to hydrido iron(II) catalyst . Recently, we reported that the classical [PSiP]-pincer iron hydride (2-Ph 2 P C 6 H 4 ) 2 Me Si Fe(H)(PMe 3 ) 2 was an efficient catalyst to dehydration of primary amides with the assistance of Lewis acid at 40 °C for 40 h …”

Section: Introductionmentioning

confidence: 99%

An Air-Stable N-Heterocyclic [PSiP] Pincer Iron Hydride and an Analogous Nitrogen Iron Hydride: Synthesis and Catalytic Dehydration of Primary Amides to Nitriles

et al. 2020

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An air-stable N-heterocyclic PSiP pincer iron hydride FeH(PMe3)2(SiPh(NCH2PPh2)2C6H4) (4) was synthesized by Si–H activation of a Ph-substituted [PSiP] pincer ligand. The analogous strong electron-donating i Pr-substituted [PSiP] pincer ligand was prepared and introduced into iron complex to give an iron nitrogen complex FeH(N2)(PMe3)(SiPh(NCH2P i Pr2)2C6H4) (6). Both 4 and 6 showed similar high efficiency for catalytic dehydration of primary amides to nitriles. Air-stable iron hydride 4 was the best catalyst for its stabilization and convenient preparation. A diverse range of cyano compounds including aromatic and aliphatic species was obtained in moderate to excellent yields. A plausible catalytic reaction mechanism was proposed.

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Lewis acid promoted dehydration of amides to nitriles catalyzed by [PSiP]‐pincer iron hydrides

Cited by 17 publications

References 40 publications

Syntheses and Structures of Gallyliron Complexes with Pyridine Ligands and Their Reactions with Methyl Acrylate

Syntheses and Structures of Gallyliron Complexes with Pyridine Ligands and Their Reactions with Methyl Acrylate

Progress in synthetic strategy and industrial preparation of aliphatic nitriles

An Air-Stable N-Heterocyclic [PSiP] Pincer Iron Hydride and an Analogous Nitrogen Iron Hydride: Synthesis and Catalytic Dehydration of Primary Amides to Nitriles

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