Rh–POP Pincer Xantphos Complexes for C–S and C–H Activation. Implications for Carbothiolation Catalysis

Ren, Peng; Pike, Sebastian D.; Pernik, Indrek; Weller, Andrew S.; Willis, Michael C.

doi:10.1021/om500984y

Cited by 54 publications

(45 citation statements)

References 66 publications

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“…21 Similarly to chloride, the oxygen atom of the mer-coordinate diphosphine of the latter has tendency to be displaced by the hydride ion. The addition of KH to 7 in tetrahydrofuran leads to the anionic pentahydride [OsH 5 {xant(P i Pr 2 ) 2 }] - (8), containing a κ 2 -P,P-bidentate diphosphine. In the presence of the crown ether 18-crown-6, yellow crystals of the [K (18-crown-6)] + -salt were obtained in 66% yield.…”

Section: Scheme 1 Formation Of H 2 By Sequential Addition Of H + Andmentioning

confidence: 99%

“…Weller and co-workers have demonstrated that 4,5-bis(diphenylphosphino)-9,9dimethylxanthene (xantphos) has the ability of changing its coordination fashion in several relevant rhodium-and iridium-mediated processes, 6 such as the hydroacylation 7 and carbothiolation 8 of alkenes and alkynes and the dehydrocoupling of amineboranes. 9 Transition metal polyhydrides are compounds having enough hydrogen atoms bonded to the metal center of a L n M fragment to form at least two different types of ligands.…”

Section: Introductionmentioning

confidence: 99%

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mer, fac, and Bidentate Coordination of an Alkyl-POP Ligand in the Chemistry of Nonclassical Osmium Hydrides

et al. 2016

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Nonclassical and classical osmium polyhydrides containing the diphosphine 9,9-dimethyl-4,5-bis(diisopropylphosphino)xanthene (xant(PPr)), coordinated in κ-mer, κ-fac, and κ-P,P fashions, have been isolated during the cyclic formation of H by means of the sequential addition of H and H or H and H to the classical trihydride OsHCl{xant(PPr)} (1). This complex adds H to form the compressed dihydride dihydrogen complex [OsCl(H···H)(η-H){xant(PPr)}] (2). Under argon, cation 2 loses H and the resulting unsaturated fragment dimerizes to give [(Os(H···H){xant(PPr)})(μ-Cl)] (3). During the transformation the phosphine changes its coordination mode from mer to fac. The benzofuran counterpart of 1, OsHCl{dbf(PPr)} (4; dbf(PPr) = 4,6-bis(diisopropylphosphino)dibenzofuran), also adds H to afford the benzofuran counterpart of 2, [OsCl(H···H)(η-H){xant(PPr)}] (5), which in contrast to the latter is stable and does not dimerize. Acetonitrile breaks the chloride bridge of 3 to form the dihydrogen [OsCl(η-H)(CHCN){xant(PPr)}] (6), regenerating the mer coordination of the diphosphine. The hydride ion also breaks the chloride bridge of 3. The addition of KH to 3 leads to 1, closing a cycle for the formation of H. Complex 1 reacts with a second hydride ion to give OsH{xant(PPr)} (7) as consequence of the displacement of the chloride. Similarly to the latter, the oxygen atom of the mer-coordinated diphosphine of 7 has a tendency to be displaced by the hydride ion. Thus, the addition of KH to 7 yields [OsH{xant(PPr)}] (8), containing a κ-P,P-diphosphine. Complex 8 is easily protonated to afford OsH{xant(PPr)} (9), which releases H to regenerate 7, closing a second cycle for the formation of molecular hydrogen.

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Section: Scheme 1 Formation Of H 2 By Sequential Addition Of H + Andmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mer, fac, and Bidentate Coordination of an Alkyl-POP Ligand in the Chemistry of Nonclassical Osmium Hydrides

et al. 2016

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“…The structure of the cationic part in 6 exhibits a slightly distorted square‐pyramidal coordination geometry at the rhodium atom with the λ 4 ‐trifluorosulfanyl ligand located in a trans position to the ether function of the phosphine with O1−Rh1−S1a and O1−Rh1−S1b angles of 169.78(17)° and 170.6(2)°, respectively. The Rh−S bond lengths (Rh1−S1a 2.195(9) Å, Rh1−S1b 2.164(11) Å) are significantly smaller when compared to the one in [Rh(SH)( t Bu xanPOP)] (Rh−S 2.2865(4) Å or in various cationic xantphos‐type Rh (III) −S complexes as for instance [Rh(xanPOP)(C 6 H 4 COMe)(SMe)][BAr F 4 ] (Rh−S 2.3373(14) Å, xanPOP=4,5‐bis(diphenylphosphino)‐9,9‐dimethylxanthene, Ar F =3,5‐(CF 3 ) 2 C 6 H 3 ) [8,11] . The SF 3 ligand displays an Rh⋅⋅⋅F interaction of 2.418(3) Å, which results in a small F1−S1a−Rh angle of 72.3(3)° as well as the significantly elongated bond between the sulfur atom and the fluorine atom F1 of 1.880(7) Å.…”

Section: Resultsmentioning

confidence: 99%

Reactivity of Xantphos‐Type Rhodium Complexes Towards SF₄: SF₃ Versus SF₂ Complex Generation

Wozniak

Sander

Braun‐Cula

et al. 2022

Chemistry A European J

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S−F‐bond activation of sulfur tetrafluoride at [Rh(Cl)(tBuxanPOP)] (1; tBuxanPOP=9,9‐dimethyl‐4,5‐bis‐(di‐tert‐butylphosphino)‐xanthene) led to the formation of the cationic complex [Rh(F)(Cl)(SF2)(tBuxanPOP)][SF5] (2 a) together with trans‐[Rh(Cl)(F)2(tBuxanPOP)] (3) and cis‐[Rh(Cl)2(F)(tBuxanPOP)] (4) which both could also be obtained by the reaction of SF5Cl with 1. In contrast to that, the conversion of SF4 at the methyl complex [Rh(Me)(tBuxanPOP)] (5) gave the isolable and room‐temperature stable cationic λ4‐trifluorosulfanyl complex [Rh(Me)(SF3)(tBuxanPOP)][SF5] (6). Treatment of 6 with the Lewis acids BF3 or AsF5 produced the dicationic difluorosulfanyl complex [Rh(Me)(SF2)(tBuxanPOP)][BF4]2 (8 a) or [Rh(Me)(SF2)(tBuxanPOP)][AsF6]2 (8 b), respectively. Refluorination of 8 a was possible with the use of dimethylamine giving [Rh(Me)(SF3)(tBuxanPOP)][BF4] (9). A reaction of 6 with trichloroisocyanuric acid (TClCA) gave the fluorido complex [Rh(F)(Cl)(SF2)(tBuxanPOP)][Cl] (2 b) together with chloromethane and SF5Cl.

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“…First, methylcobalt(I) I should be generated from Co(acac) 2 , Xantphos, and AlMe 3 [ 28 – 29 ]. Oxidative addition of the allylic C(sp 3 )–H bond to I would proceed to afford η 3 -allylcobalt(III) intermediate II , which is tautomerized to η 1 -allylcobalt(III) III by the assistance of the oxygen atom in the Xantphos ligand [ 30 ]. When using α-olefin as a substrate, the cobalt atom should be located at the terminal position due to the avoidance of steric repulsion between the bulky Xantphos ligand and an alkyl substitution (similar to the case of nucleophilic η 1 -allylpalladium species [ 31 – 39 ]), whereas the cobalt atom preferred to reside at the internal position when allylarenes and 1,4-dienes were employed in our previous studies [ 28 – 29 ].…”

Section: Resultsmentioning

confidence: 99%

Cobalt-catalyzed nucleophilic addition of the allylic C(sp³)–H bond of simple alkenes to ketones

Mita¹,

Uchiyama²,

Michigami³

et al. 2018

Beilstein J. Org. Chem.

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Rh–POP Pincer Xantphos Complexes for C–S and C–H Activation. Implications for Carbothiolation Catalysis

Cited by 54 publications

References 66 publications

mer, fac, and Bidentate Coordination of an Alkyl-POP Ligand in the Chemistry of Nonclassical Osmium Hydrides

mer, fac, and Bidentate Coordination of an Alkyl-POP Ligand in the Chemistry of Nonclassical Osmium Hydrides

Reactivity of Xantphos‐Type Rhodium Complexes Towards SF₄: SF₃ Versus SF₂ Complex Generation

Cobalt-catalyzed nucleophilic addition of the allylic C(sp³)–H bond of simple alkenes to ketones

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Rh–POP Pincer Xantphos Complexes for C–S and C–H Activation. Implications for Carbothiolation Catalysis

Cited by 54 publications

References 66 publications

mer, fac, and Bidentate Coordination of an Alkyl-POP Ligand in the Chemistry of Nonclassical Osmium Hydrides

mer, fac, and Bidentate Coordination of an Alkyl-POP Ligand in the Chemistry of Nonclassical Osmium Hydrides

Reactivity of Xantphos‐Type Rhodium Complexes Towards SF4: SF3 Versus SF2 Complex Generation

Cobalt-catalyzed nucleophilic addition of the allylic C(sp3)–H bond of simple alkenes to ketones

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Reactivity of Xantphos‐Type Rhodium Complexes Towards SF₄: SF₃ Versus SF₂ Complex Generation

Cobalt-catalyzed nucleophilic addition of the allylic C(sp³)–H bond of simple alkenes to ketones