The synthesis and reactivity of geometrically constrained tricoordinate phosphorus (σ(3)-P) compounds supported by tridentate triamide chelates (N[o-NR-C6H4]2(3-); R = Me or (i)Pr) are reported. Studies indicate that 2 (P{N[o-NMe-C6H4]2}) adopts a Cs-symmetric structure in the solid state. Variable-temperature NMR studies demonstrate a low-energy inversion at phosphorus in solution (ΔG(‡)(exptl)(298) = 10.7(5) kcal/mol), for which DFT calculations implicate an edge-inversion mechanism via a metastable C2-symmetric intermediate. In terms of reactivity, compound 2 exhibits poor nucleophilicity, but undergoes oxidative addition at ambient temperature of diverse O-H- and N-H-containing compounds (including alcohols, phenols, carboxylic acids, amines, and anilines). The resulting pentacoordinate adducts 2·[H][OR] and 2·[H][NHR] are characterized by multinuclear NMR spectroscopy and X-ray crystallography, and their structures (which span the pseudorotation coordinate between trigonal bipyramidal and square planar) are evaluated in terms of negative hyperconjugation. At elevated temperatures, the oxidative addition is shown to be reversible for volatile alcohols and amines.
Studies on the stoichiometric and catalytic reactivity of a geometrically constrained phosphorous triamide 1 with pinacolborane (HBpin) are reported. The addition of HBpin to phosphorous triamide 1 results in cleavage of the B-H bond of pinacolborane through addition across electrophilic phosphorus and nucleophilic N-methylanilide sites in a cooperative fashion. The kinetics of this process of were investigated by NMR spectroscopy, with the determined overall second order empirical rate law given by ν = − k[1][HBpin] where k = 4.76 × 10−5 M−1s−1 at 25 °C. The B–H bond activation process produces a P-hydrido-1,3,2-diazaphospholene intermediate 2, which exhibits hydridic reactivity capable of reacting with imines to give phosphorous triamide intermediates, as confirmed by independent synthesis. These phosphorous triamide intermediates are typically short-lived, evolving with elimination of the N-borylamine product of imine hydroboration with regeneration of the deformed phosphorous triamide 1. The kinetics of this latter process are shown to be first-order, indicative of a unimolecular mechanism. Consequently, catalytic hydroboration of a variety of imine substrates can be realized with 1 as catalyst and HBpin as terminal reagent. A mechanistic proposal implicating a P–N cooperative mechanism for catalysis that incorporates the various independently verified stoichiometric steps is presented and a comparison to related phosphorus-based systems is offered.
The
tin–tin triple bond in the distannyne Ar
iPr4SnSnAr
iPr4, Ar
iPr4 = C6H3-2,6(C6H3-2,6-iPr2)2, undergoes reversible
cleavage in deuterated toluene to afford two
:SṅAr
iPr4 radicals in solution
as shown by 1H nuclear magnetic resonance and electron
paramagnetic resonance spectroscopy. Variable temperature data afforded
an enthalpy of dissociation of ΔH
diss = 17.2 ± 1.7 kcal mol–1 via van‘t
Hoff analysis.
The diarylstannylenes, Sn(AriPr4)2 and Sn(AriPr6)2, (AriPr4 = C6H3-2,6-(C6H3-2,6-iPr2)2, AriPr6 = C6H3-2,6-(C6H2-2,4,6-iPr3)2), undergo a facile migratory insertion reaction with ethylene at 60 °C to afford the alkyl aryl stannylenes AriPr4SnCH2CH2AriPr4 and AriPr6SnCH2CH2AriPr6 which were characterized via1H, 13C and 119Sn NMR, UV-vis and IR spectroscopy, as well as by X-ray crystallography.
The diarylstannylene, :Sn(Ar ) (Ar = CH-2,6-(CH-2,6- Pr)), undergoes C-H metathesis with toluene, m-xylene, or mesitylene in solutions of these solvents at 80 °C. The products, [Ar Sn(CHAr)] (Aryl=CH (1a), CH-3-Me (1b), CH-3,5-Me(1c)) were characterized via H,C and Sn NMR, UV-vis and IR spectroscopy, and by X-ray crystallography for 1a and 1b. A stoichiometric amount of the arene, ArH, was also produced in these reactions. The use of EPR spectroscopy indicated the presence of a new type of one-coordinate, tin-centered radical, :ṠnAr , resulting from Sn-C bond cleavage in Sn(Ar).
The facile heterodehydrocoupling of a range of primary or secondary amines and even ammonia with pinacolborane (HBPin) was accomplished using {ArSn(μ-OMe)} (1, Ar = CH-2,6-(CH-2,4,6-Me)) as pre-catalysts for a catalytically active tin(ii) hydride. The more sterically hindered pre-catalyst 2, {ArSn(μ-OMe)} (Ar = CH-2,6-(CH-2,6-iPr)) facilitated the dehydrocoupling only of primary amines with HBPin, and at an increased rate relative to the less crowded {ArSn(μ-OMe)}. Also presented is {ArSn(μ-NEt)} (3), which can be converted into the structurally characterizable {ArSn(μ-NEt)(μ-H)SnAr} (4) via the addition of pinacol borane. This, alongside stoichiometric studies, give insight into the mechanism of the catalysis.
The diarylgermylene Ge(Ar Me6 ) 2 (Ar Me6 = C 6 H 3 -2,6-(C 6 H 2 -2,4,6-Me 3 ) 2 ) is shown to react reversibly with the four unstrained alkynes 3-hexyne, diphenylacetylene, trimethylsilylacetylene, and phenylacetylene at ambient temperature in toluene. The germirene products (Ar Me6 ) 2 GeC(R)C(R′) (R, R′ = Et, Et (1a), Ph, Ph (1b), H, SiMe 3 (1c), H, Ph (1d) were characterized by 1 H and 13 C NMR spectroscopy and by X-ray crystallography in the case of 1a and 1d. The thermodynamic parameters of the reactions were determined by variable-temperature 1 H NMR spectroscopy, and the experimental Gibbs free energies indicated their near-thermoneutrality and relatively weak alkyne coordination.
Herein, we report the characterization of a novel germanium hydride radical arising from the photolysis/thermolysis of the diarylgermylene GeR 2 [R = terphenyl:) 2 ] by using electron paramagnetic resonance spectroscopy complemented with theoretical calculations. The trapped germanium radical is a pseudoplanar S = 1 / 2 germanium(III) hydride, i.e.,• GeHRR′ (R = Ar iPr4 or Ar iPr6 ; R′ is a quaternary carbon), with a g tensor of [2.029, 2.003, 1.990], a 73 Ge hyperfine tensor of [−10, −90, −10] MHz, and a strong 1 H hyperfine tensor of [−23.0, −20.5, −31.5] MHz for the hydride. The germanium(III) hydride radical is a result of the insertion of a germanium(I) radical intermediate (:G ̇eR) in a C−H bond, due to the greater reactivity of the germanium(I) radical intermediate in comparison with the tin(I) counterpart that we trapped earlier.
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