Activation of an Au−Cl Bond by a Pendent Sb<sup>III</sup> Lewis Acid: Impact on Structure and Catalytic Activity

Jones, James S.; Gabbaı̈, François P.

doi:10.1002/chem.201604521

Cited by 50 publications

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“…Recent efforts in the chemistry of organoantimony(III) have established that derivatives such as I and II readily bind halide anions (Figure ) by donation into the σ* orbital (Figure ) . Based on the same principle, we also found that antimony(III) halides could serve to promote the activation of transition metals either by direct interaction with the metal ( III ) or anion abstraction ( IV ) (Figure ).…”

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“…[1] Antimony derivatives,b ecause of their intrinsically higher Lewis acidity, [2] are also drawing considerable attention both in the areas of small-molecule activation and catalysis, [3] as well as in anion complexation. [7] Based on the same principle,w ea lso found that antimony(III) halides could serve to promote the activation of transition metals either by direct interaction with the metal (III) [8] or anion abstraction (IV) [9] (Figure 1). [7] Based on the same principle,w ea lso found that antimony(III) halides could serve to promote the activation of transition metals either by direct interaction with the metal (III) [8] or anion abstraction (IV) [9] (Figure 1).…”

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Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

et al. 2018

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The development of group 15 Lewis acids is an area of active investigation that has led to numerous advances in anion sensing and catalysis. While phosphorus has drawn considerable attention, emerging research shows that organoantimony(III) reagents may also act as potent Lewis acids. Comparison of the properties of SbPh , Sb(C F ) , and SbAr with those of their tetrachlorocatecholate analogues SbPh Cat, Sb(C F ) Cat, and SbAr Cat (Cat=o-O C Cl , Ar =3,5-(CF ) C H ) demonstrates that the Lewis acidity of electron deficient organoantimony(III) reagents can be readily enhanced by oxidation to the +V state-as verified by binding studies, organic reaction catalysis, and computational studies. The results are rationalized by explaining that oxidation of the antimony center leads to a lowering of the accepting σ* orbital and a deeper carving of the associated σ-hole.

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Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

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“…[4] Recent efforts in the chemistry of organoantimony(III) [5] have established that derivatives such as I [6] and II [7] readily bind halide anions ( Figure 1) by donation into the s*orbital (Figure 2). [7] Based on the same principle,w ea lso found that antimony(III) halides could serve to promote the activation of transition metals either by direct interaction with the metal (III) [8] or anion abstraction (IV) [9] (Figure 1).…”

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Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

et al. 2018

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The development of group 15 Lewis acids is an area of active investigation that has led to numerous advances in anion sensing and catalysis. While phosphorus has drawn considerable attention, emerging research shows that organoantimony(III) reagents may also act as potent Lewis acids. Comparison of the properties of SbPh3, Sb(C6F5)3, and SbArF3 with those of their tetrachlorocatecholate analogues SbPh3Cat, Sb(C6F5)3Cat, and SbArF3Cat (Cat=o‐O2C6Cl4, ArF=3,5‐(CF3)2C6H3) demonstrates that the Lewis acidity of electron deficient organoantimony(III) reagents can be readily enhanced by oxidation to the +V state—as verified by binding studies, organic reaction catalysis, and computational studies. The results are rationalized by explaining that oxidation of the antimony center leads to a lowering of the accepting σ* orbital and a deeper carving of the associated σ‐hole.

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“…Although a parallel is often drawn with the ubiquitous phosphine ligands, stibines display several atypical traits and can, for example, undergo redox reactions without dissociation of the coordinated metal [5][6][7][8][9][10]. Moreover, while phosphines mostly act as two-electron donor spectator ligands, stibines have been shown to display Lewis acidic properties, even when coordinated to a transition metal [11][12][13][14][15][16][17][18][19][20][21][22]. These Lewis acidic properties manifest in the formation of long contacts between the antimony center of cationic complexes and counteranions as in complex [A] + which was isolated by Reid (Figure 1) [11].…”

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Structural Evidence for Pnictogen-Centered Lewis Acidity in Cationic Platinum-Stibine Complexes Featuring Pendent Amino or Ammonium Groups

Rodrigues

Gabbaı̈

2021

Molecules

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As part of our continuing interest in the chemistry of cationic antimony Lewis acids as ligands for late transition metals, we have now investigated the synthesis of platinum complexes featuring a triarylstibine ligand substituted by an o-[(dimethylamino)methyl]phenyl group referred to as ArN. More specifically, we describe the synthesis of the amino stibine ligand Ph2SbArN (L) and its platinum dichloride complex [LPtCl]Cl which exists as a chloride salt and which shows weak coordination of the amino group to the antimony center. We also report the conversion of [LPtCl]Cl into a tricationic complex [LHPt(SMe2)]3+ which has been isolated as a tris-triflate salt after reaction of [LPtCl]Cl with SMe2, HOTf and AgOTf. Finally, we show that [LHPt(SMe2)][OTf]3 acts as a catalyst for the cyclization of 2-allyl-2-(2-propynyl)malonate.

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Activation of an Au−Cl Bond by a Pendent Sb^III Lewis Acid: Impact on Structure and Catalytic Activity

Cited by 50 publications

References 106 publications

Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

Structural Evidence for Pnictogen-Centered Lewis Acidity in Cationic Platinum-Stibine Complexes Featuring Pendent Amino or Ammonium Groups

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Activation of an Au−Cl Bond by a Pendent SbIII Lewis Acid: Impact on Structure and Catalytic Activity

Cited by 50 publications

References 106 publications

Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

Digging the Sigma‐Hole of Organoantimony Lewis Acids by Oxidation

Structural Evidence for Pnictogen-Centered Lewis Acidity in Cationic Platinum-Stibine Complexes Featuring Pendent Amino or Ammonium Groups

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Activation of an Au−Cl Bond by a Pendent Sb^III Lewis Acid: Impact on Structure and Catalytic Activity