Your search keyword '"Toste FD"' showing total 10 results

1. Halide-Dependent Mechanisms of Reductive Elimination from Gold(III).

Author

Winston MS, Wolf WJ, and Toste FD

Subjects

Bromides chemistry, Chlorides chemistry, Fluorides chemistry, Hot Temperature, Iodides chemistry, Ligands, Models, Molecular, Oxidation-Reduction, Thermodynamics, Halogens chemistry, Organogold Compounds chemistry

Abstract

Two unique organometallic halide series (Ph3P)Au(4-Me-C6H4)(CF3)(X) and (Cy3P)Au(4-F-C6H4)(CF3)(X) (X = I, Br, Cl, F) have been synthesized. The PPh3-supported complexes can undergo both C(aryl)-X and C(aryl)-CF3 reductive elimination. Mechanistic studies of thermolysis at 122 °C reveal a dramatic reactivity and kinetic selectivity dependence on halide ligand. For X = I or F, zero-order kinetic behavior is observed, while for X = Cl or Br, kinetic studies implicate product catalysis. The selectivity for C(aryl)-CF3 bond formation increases in the order X = I < Br < Cl < F, with exclusively C(aryl)-I bond formation when X = I, and exclusively C(aryl)-CF3 bond formation when X = F. Thermodynamic measurements show that Au(III)-X bond dissociation energies increase in the order X = I < Br < Cl, and that ground state Au(III)-X bond strength ultimately dictates selectivities for C(aryl)-X and C(aryl)-CF3 reductive elimination.

Published

2015

2. Development of catalysts and ligands for enantioselective gold catalysis.

Author

Wang YM, Lackner AD, and Toste FD

Subjects

Alkadienes chemistry, Carbon, Catalysis, Ligands, Methane analogs & derivatives, Molecular Structure, Organic Chemistry Phenomena, Organogold Compounds chemical synthesis, Organophosphorus Compounds chemistry, Phosphines chemistry, Stereoisomerism, Gold chemistry, Organogold Compounds chemistry

Abstract

During the past decade, the use of Au(I) complexes for the catalytic activation of C-C π-bonds has been investigated intensely. Over this time period, the development of homogeneous gold catalysis has been extraordinarily rapid and has yielded a host of mild and selective methods for the formation of carbon-carbon and carbon-heteroatom bonds. The facile formation of new bonds facilitated by gold naturally led to efforts toward rendering these transformations enantioselective. In this Account, we survey the development of catalysts and ligands for enantioselective gold catalysis by our research group as well as related work by others. We also discuss some of our strategies to address the challenges of enantioselective gold(I) catalysis. Early on, our work with enantioselective gold-catalyzed transformations focused on bis(phosphinegold) complexes derived from axially chiral scaffolds. Although these complexes were highly successful in some reactions like cyclopropanation, the careful choice of the weakly coordinating ligand (or counterion) was necessary to obtain high levels of enantioselectivity for the case of allene hydroamination. These counterion effects led us to use the anion itself as a source of chirality, which was successful in the case of allene hydroalkoxylation. In general, these tactics enhance the steric influence around the reactive gold center beyond the two-coordinate ligand environment. The use of binuclear complexes allowed us to use the second gold center and its associated ligand (or counterion) to exert a further steric influence. In a similar vein, we employed a chiral anion (in place of or in addition to a chiral ligand) to move the chiral information closer to the reactive center. In order to expand the scope of reactions amenable to enantioselective gold catalysis to cycloadditions and other carbocyclization processes, we also developed a new class of mononuclear phosphite and phosphoramidite ligands to supplement the previously widely utilized phosphines. However, we needed to judiciously design the steric environment to create "walls" that enclose the gold center. We also successfully applied these same considerations to the development of binuclear carbene ligands for gold. Finally, we describe the design of bifunctional urea-monophosphine ligands used in a gold-catalyzed three-component coupling.

Published

2014

3. Gold(I)-catalyzed enantioselective carboalkoxylation of alkynes.

Author

Zi W and Toste FD

Subjects

Catalysis, Cyclization, Indans chemistry, Molecular Structure, Stereoisomerism, Alkynes chemistry, Indans chemical synthesis, Organogold Compounds chemistry

Abstract

A highly enantioselective carboalkoxylation of alkynes catalyzed by cationic (DTBM-MeO-Biphep)gold(I) complexes is reported. Various optically active β-alkoxyindanone derivatives were obtained in good yields with high enantioselectivities. Furthermore, this methodology was extended to the enantioselective synthesis of 3-methoxycyclopentenones. The reaction is proposed to proceed through an enantioselective cyclization of intermediates containing vinylgold(I) and prochiral oxocarbenium moieties.

Published

2013

4. Chiral Brønsted acid from a cationic gold(I) complex: catalytic enantioselective protonation of silyl enol ethers of ketones.

Author

Cheon CH, Kanno O, and Toste FD

Subjects

Catalysis, Cations chemistry, Ethers chemistry, Ketones chemistry, Stereoisomerism, Acids chemistry, Organogold Compounds chemistry, Phosphines chemistry

Abstract

A chiral Brønsted acid has been developed from a cationic gold(I) disphosphine complex in the presence of alcoholic solvent and applied to the enantioselective protonation reaction of silyl enol ethers of ketones. Various optically active cyclic ketones were obtained in excellent yields and high enantioselectivities, including cyclic ketones bearing aliphatic substrates at the α-position. Furthermore, the application of this Brønsted acid was extended to the first Brønsted acid-catalyzed enantioselective protonation reaction of silyl enol ethers of acyclic substrates, regardless of their E/Z ratio.

Published

2011

5. On the impact of steric and electronic properties of ligands on gold(I)-catalyzed cycloaddition reactions.

Author

Benitez D, Tkatchouk E, Gonzalez AZ, Goddard WA 3rd, and Toste FD

Subjects

Alkadienes chemistry, Catalysis, Cyclization, Molecular Structure, Alkadienes chemical synthesis, Gold chemistry, Organogold Compounds chemistry

Abstract

It is shown that [4 + 3] and [4 + 2] cycloaddition pathways are accessible in the Au(I) catalysis of allene-dienes. Seven-membered ring gold-stabilized carbenes, originating from the [4 + 3] cycloaddition process, are unstable and can rearrange via a 1,2-H or a 1,2-alkyl shift to yield six- and seven-membered products. Both steric and electronic properties of the AuL(+) catalyst affect the electronic structure of the intermediate gold-stabilized carbene and its subsequent reactivity.

Published

2009

6. A bonding model for gold(I) carbene complexes.

Author

Benitez D, Shapiro ND, Tkatchouk E, Wang Y, Goddard WA 3rd, and Toste FD

Subjects

Cyclopropanes chemical synthesis, Cyclopropanes chemistry, Ligands, Methane chemistry, Molecular Structure, Gold chemistry, Methane analogs & derivatives, Organogold Compounds chemistry

Abstract

The last decade has witnessed dramatic growth in the number of reactions catalyzed by electrophilic gold complexes. While proposed mechanisms often invoke the intermediacy of gold-stabilized cationic species, the nature of bonding in these intermediates remains unclear. Herein, we propose that the carbon-gold bond in these intermediates is comprised of varying degrees of both sigma and pi-bonding; however, the overall bond order is generally less than or equal to unity. The bonding in a given gold-stabilized intermediate, and the position of this intermediate on a continuum ranging from gold-stabilized singlet carbene to gold-coordinated carbocation, is dictated by the carbene substituents and the ancillary ligand. Experiments show that the correlation between bonding and reactivity is reflected in the yield of gold-catalyzed cyclopropanation reactions.

Published

2009

7. Ligand effects in homogeneous Au catalysis.

Author

Gorin DJ, Sherry BD, and Toste FD

Subjects

Alcohols chemistry, Alkenes chemistry, Alkynes chemistry, Catalysis, Cyclization, Esters chemistry, Ligands, Molecular Conformation, Organic Chemicals chemistry, Organogold Compounds chemical synthesis, Stereoisomerism, Gold chemistry, Organic Chemicals chemical synthesis, Organogold Compounds chemistry

Published

2008

8. Gold-catalyzed cycloisomerization of 1,5-allenynes via dual activation of an ene reaction.

Author

Cheong PH, Morganelli P, Luzung MR, Houk KN, and Toste FD

Subjects

Alkadienes chemistry, Catalysis, Cyclization, Models, Chemical, Molecular Structure, Stereoisomerism, Alkadienes chemical synthesis, Alkynes chemistry, Organogold Compounds chemistry

Abstract

Tris(triphenylphosphinegold) oxonium tetrafluoroborate, [(Ph3PAu)3O]BF4, catalyzes the rearrangement of 1,5-allenynes to produce cross-conjugated trienes. Experimental and computational evidence shows that the ene reaction proceeds through a unique nucleophilic addition of an allene double bond to a cationic phosphinegold(I)-complexed phosphinegold(I) acetylide, followed by a 1,5-hydrogen shift.

Published

2008

9. Fluorenes and styrenes by Au(I)-catalyzed annulation of enynes and alkynes.

Author

Gorin DJ, Watson ID, and Toste FD

Subjects

Catalysis, Cyclization, Fluorenes chemistry, Molecular Structure, Stereoisomerism, Styrenes chemistry, Alkynes chemistry, Fluorenes chemical synthesis, Gold chemistry, Organogold Compounds chemistry, Styrenes chemical synthesis

Abstract

Intermolecular annulation of enynes and propargyl esters to selectively produce styrenes or fluorenes is reported. The divergent arene syntheses involve a Au-catalyzed, two-pot, multistep process proceeding by cis-diastereoselective cyclopropanation, cycloisomerization, and, finally, annulation or elimination.

Published

2008

10. A powerful chiral counterion strategy for asymmetric transition metal catalysis.

Author

Hamilton GL, Kang EJ, Mba M, and Toste FD

Subjects

Amination, Anions chemistry, Cyclization, Ligands, Solvents, Alkadienes chemistry, Catalysis, Gold chemistry, Organogold Compounds chemistry, Phosphates chemistry, Silver Compounds chemistry, Stereoisomerism

Abstract

Traditionally, transition metal-catalyzed enantioselective transformations rely on chiral ligands tightly bound to the metal to induce asymmetric product distributions. Here we report high enantioselectivities conferred by a chiral counterion in a metal-catalyzed reaction. Two different transformations catalyzed by cationic gold(I) complexes generated products in 90 to 99% enantiomeric excess with the use of chiral binaphthol-derived phosphate anions. Furthermore, we show that the chiral counterion can be combined additively with chiral ligands to enable an asymmetric transformation that cannot be achieved by either method alone. This concept of relaying chiral information via an ion pair should be applicable to a vast number of metal-mediated processes.

Published

2007