Insight into the Reaction of a Dinuclear Phosphinidene Complex with Nitriles

Seidl, Michael; Weinzierl, Rudolf; Timoshkin, Alexey Y.; Scheer, Manfred

doi:10.1002/chem.201504954

Cited by 11 publications

(5 citation statements)

References 65 publications

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“…The reaction of the phosphinidene complex 5 towards aniline and 1,4-benzodinitrile yielded two new phosphinidene complexes after formation of new PN bonds (Scheme 29) [57]. In the first reaction, HCp* is eliminated to give the aminophosphinidene complex 55, while the second reaction involves nitrile insertion into the PCp* bond to eventually yield the tetranuclear complex 56.…”

Section: Scheme 28mentioning

confidence: 99%

“…The reactivity of the ditungsten complex 5 towards molecules containing multiple CN bonds such as nitriles [57,102], isocyanides [103], carbodiimides [104] and carboimidophosphenes [105] has been examined in detail (Schemes 72 and 73). Reaction with acetonitrile proceeded at 293 K to give a 1,2-dihydro-1,3,2-diazaphosphinine derivative 147a following from double NCMe insertion into the PC bond of the phosphinidene ligand, with CC bond formation and subsequent migration of βH atoms of one acetonitrile to the N atoms.…”

Section: Reactions With Molecules Containing Cn Multiple Bondsmentioning

confidence: 99%

“…In contrast, reaction with malononitrile in refluxing toluene led to a derivative of type 147 now bearing two Cp* substituents, along with other thermolysis products (Scheme 72). The reactions of 5 with malononitrile and acetonitrile represent the first examples in which two nitriles form a -diketiminate assisted by a phosphinidene complex [57].…”

Section: Reactions With Molecules Containing Cn Multiple Bondsmentioning

confidence: 99%

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Phosphinidene-bridged binuclear complexes

Garcı́a

García‐Vivó

Ramos

et al. 2017

Coordination Chemistry Reviews

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This article contains a comprehensive review of the work carried out within the last three decades on the synthesis, structural studies and reactivity of the binuclear complexes of transition and lanthanide elements bearing bridging phosphinidene (PR) ligands. The latter are grouped into three different classes according to their geometry and electronic distribution: pyramidal, symmetric planar trigonal and asymmetric planar trigonal. Different reactivity patterns can be then outlined for each of these classes of metal complexes, which differ in many ways from those characterizing the extensively studied chemical behaviour of mononuclear phosphinidene complexes.

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Section: Scheme 28mentioning

confidence: 99%

Section: Reactions With Molecules Containing Cn Multiple Bondsmentioning

confidence: 99%

Section: Reactions With Molecules Containing Cn Multiple Bondsmentioning

confidence: 99%

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Phosphinidene-bridged binuclear complexes

Garcı́a

García‐Vivó

Ramos

et al. 2017

Coordination Chemistry Reviews

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“…They represent very reactive R–E molecules (E = P, As, Sb or Bi); therefore, their synthesis is not trivial and still remains a challenging task. For a long time, these compounds could not be isolated and were studied especially as very reactive intermediates or as ligands for transition metals that often exhibit interesting reactivity. , Lighter pnictinidenes, especially phosphinidenes, could be generated in situ from suitable metastable precursors and transferred to other substrates in a controlled manner as well …”

Section: Introductionmentioning

confidence: 99%

Exploring Differences between Bis(aldimino)- and amino-aldimino-N,C,N-Pincer-Stabilized Pnictinidenes: Limits of Synthesis, Structure, and Reversible Tautomerization-Controlled Oxidation

et al. 2022

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Two types of N,C,N-chelated pnictinidenes, i.e., [2-(RNHCH2)-6-(RN  CH)C6H3]E (1-E-R) and [2,6-(RNCH)2C6H3]E (2-E-R, where E = As, Sb, Bi), are targeted in this study. 2-E-R could be obtained by simple reduction of respective precursors [2,6-(RNCH)2C6H3]ECl2 (i.e., (2-E-R)Cl2) with KC8 for E = As, Sb, or Bi with R being tBu, Ad, or Dipp. By contrast, the utilization of a bulky hydride, i.e., K-selectride, allowed the isolation of 1-E-R for E = As or Sb and R = Dipp, while the utilization of other pincer ligands, where R = tBu or Ad, led only to mixtures of both 1-E-R and 2-E-R. For bismuth, even the Dipp-substituted pincer ligand provided a mixture of 1-Bi-Dipp and 2-Bi-Dipp only. The structures and chemical properties of these sets of compounds, i.e., 1-E-Dipp, 2-E- t Bu, and 2-E-Dipp, were compared using X-ray diffraction analysis, UV–vis spectroscopy including an extensive theoretical study, and CV measurements. The oxidation of 2-E-Dipp (E = As, Sb, Bi) by air resulted only in the formation of complicated mixtures, while oxidation of 1-E-Dipp (E = As or Sb) cleanly produces (1′-E-Dipp)OH as a result of a tautomeric NH → OH shift at elusive oxides (1-E-Dipp)O under formation of a new E–N covalent bond. To examine the potential of such tautomerization-driven stabilization of oxidation products, the reactivity of 1-E-Dipp (E = As or Sb) toward other chalcogens is also reported, including a theoretical study.

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“…The bridging pentelidene complexes [Cp*E{W(CO) 5 } 2 ] (Cp* = pentamethylcyclopentadienyl, E = P, As) have been a subject of interest in our group for almost 20 years and thus their reaction behavior towards nucleophiles such as phosphines [1][2] and nitriles [3] has been investigated thoroughly. In contrast, since their discovery in 1978 [4], trigonal-planar stibinidene complexes have not been investigated much [5].…”

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confidence: 99%