Gold peroxide complexes and the conversion of hydroperoxides into gold hydrides by successive oxygen-transfer reactions

Roşca, Dragoş‐Adrian; Wright, Joseph A.; Hughes, David L.; Bochmann, Manfred

doi:10.1038/ncomms3167

Cited by 132 publications

(85 citation statements)

References 56 publications

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“…Given that square‐planar gold(III) compounds of type 1 stabilized by rigid pincer ligands have no coordination sites available for substrate binding, the mechanism of this alkyne hydroauration was not obvious. Earlier computational attempts to search for the coordination of a phosphine to the metal perpendicular to the molecular plane had failed to find any evidence for an energy minimum . Computations with an alkyne as a possible ligand gave analogous results: there was no evidence for a coordinative alkyne–gold interaction.…”

Section: Figurecontrasting

confidence: 71%

Stereo‐ and Regioselective Alkyne Hydrometallation with Gold(III) Hydrides

et al. 2016

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The hydroauration of internal and terminal alkynes by gold(III) hydride complexes [(C^N^C)AuH] was found to be mediated by radicals and proceeds by an unexpected binuclear outer-sphere mechanism to cleanly form transinsertion products.R adical precursors such as azobisisobutyronitrile lead to ad rastic rate enhancement. DFT calculations support the proposed radical mechanism, with very lowa ctivation barriers,a nd rule out mononuclear mechanistic alternatives.T hese alkyne hydroaurations are highly regio-and stereospecific for the formation of Z-vinyl isomers,with Z/E ratios of > 99:1 in most cases.

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Section: Figurecontrasting

confidence: 71%

Stereo‐ and Regioselective Alkyne Hydrometallation with Gold(III) Hydrides

et al. 2016

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“…[49] First, (15) with tert-butyl hydroperoxide in toluene at room temperature.S imilarly,t he reaction of 15 with 30 % aqueous hydrogen peroxide produced the Au III -hydroperoxide complex [(C^N^C)AuOOH] (28). Taking advantage of the stable Au III -hydroxo complex [(C^N^C)AuOH] (15)a nd the [(C^N^C)AuH] complex 24, Bochmann and co-workers set out to intensively study the intrinsic reactivity of Au III À Ob onds in this context (Scheme 7).…”

Section: [(C^n^c)au(oxo)] and [(C^n^c)au(peroxo)] Complexesmentioning

confidence: 99%

Cyclometalated Gold(III) Complexes: Synthesis, Reactivity, and Physicochemical Properties

2017

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This Review showcases the ability of bi- and tridentate ligands to stabilize gold in high oxidation states through the formation of mono- and biscyclometalated gold(III) complexes. In-depth studies on the synthesis, intrinsic reactivity, catalytic relevance, and photophysical properties of stabilized gold(III) species have been carried out, setting the stage for exciting developments in various research areas, such as catalysis, inorganic and bioinorganic chemistry, ligand design, and materials science.

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“…7 The existence of competing alternative reaction channels in the transformation of 1 to 2 was also indicated by the appearance of signals due to the known 11 Au(II) complex (C ∧ N ∧ C)Au–Au(C ∧ N ∧ C) ( 3 ). The final 2 : 3 molar ratio was 3:1.…”

Section: Resultsmentioning

confidence: 98%

“…7 Following the same bond strength trend, gold hydrides can even be formed from suitable reactive gold–carbon compounds, such as Au–COOH species, where facile transformation to the hydride by CO 2 elimination was observed. 8 Calculations also show that the O abstraction from the gold methoxide 1 to give the gold methyl complex 2 is energetically favorable (Scheme 1).…”

Section: Introductionmentioning

confidence: 89%

Formation of Gold(III) Alkyls from Gold Alkoxide Complexes

et al. 2017

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The gold(III) methoxide complex (C∧N∧C)AuOMe (1) reacts with tris(p-tolyl)phosphine in benzene at room temperature under O abstraction to give the methylgold product (C∧N∧C)AuMe (2) together with O=P(p-tol)3 ((C∧N∧C) = [2,6-(C6H3tBu-4)2pyridine]2–). Calculations show that this reaction is energetically favorable (ΔG = −32.3 kcal mol–1). The side products in this reaction, the Au(II) complex [Au(C∧N∧C)]2 (3) and the phosphorane (p-tol)3P(OMe)2, suggest that at least two reaction pathways may operate, including one involving (C∧N∧C)Au• radicals. Attempts to model the reaction by DFT methods showed that PPh3 can approach 1 to give a near-linear Au–O–P arrangement, without phosphine coordination to gold. The analogous reaction of (C∧N∧C)AuOEt, on the other hand, gives exclusively a mixture of 3 and (p-tol)3P(OEt)2. Whereas the reaction of (C∧N∧C)AuOR (R = But, p-C6H4F) with P(p-tol)3 proceeds over a period of hours, compounds with R = CH2CF3, CH(CF3)2 react almost instantaneously, to give 3 and O=P(p-tol)3. In chlorinated solvents, treatment of the alkoxides (C∧N∧C)AuOR with phosphines generates [(C∧N∧C)Au(PR3)]Cl, via Cl abstraction from the solvent. Attempts to extend the synthesis of gold(III) alkoxides to allyl alcohols were unsuccessful; the reaction of (C∧N∧C)AuOH with an excess of CH2=CHCH2OH in toluene led instead to allyl alcohol isomerization to give a mixture of gold alkyls, (C∧N∧C)AuR′ (R′ = −CH2CH2CHO (10), −CH2CH(CH2OH)OCH2CH=CH2 (11)), while 2-methallyl alcohol affords R′ = CH2CH(Me)CHO (12). The crystal structure of 11 was determined. The formation of Au–C instead of the expected Au–O products is in line with the trend in metal–ligand bond dissociation energies for Au(III): M–H > M–C > M–O.

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Gold peroxide complexes and the conversion of hydroperoxides into gold hydrides by successive oxygen-transfer reactions

Cited by 132 publications

References 56 publications

Stereo‐ and Regioselective Alkyne Hydrometallation with Gold(III) Hydrides

Stereo‐ and Regioselective Alkyne Hydrometallation with Gold(III) Hydrides

Cyclometalated Gold(III) Complexes: Synthesis, Reactivity, and Physicochemical Properties

Formation of Gold(III) Alkyls from Gold Alkoxide Complexes

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