Your search keyword '"David Y. Wang"' showing total 5 results

1. Origin of Regioselectivity in the Dehydrogenation of Alkanes by Pincer–Iridium Complexes: A Combined Experimental and Computational Study

Author

Michael J. Blessent, Tian Zhou, Karsten Krogh-Jespersen, David Y. Wang, Soumik Biswas, Benjamin M. Gordon, Alan S. Goldman, and Santanu Malakar

Subjects

chemistry, chemistry.chemical_element, Regioselectivity, Dehydrogenation, General Chemistry, Iridium, Medicinal chemistry, Catalysis, Pincer movement

Published

2021

2. Enantioselective Photoredox Catalysis Enabled by Proton-Coupled Electron Transfer: Development of an Asymmetric Aza-Pinacol Cyclization

Author

Lydia J. Rono, David Y. Wang, Michael F. Armstrong, Robert R. Knowles, and Hatice G. Yayla

Subjects

Radical, Enantioselective synthesis, Photoredox catalysis, General Chemistry, Photochemistry, Biochemistry, Catalysis, chemistry.chemical_compound, Electron transfer, Colloid and Surface Chemistry, Ketyl, chemistry, Proton-coupled electron transfer, Brønsted–Lowry acid–base theory

Abstract

The first highly enantioselective catalytic protocol for the reductive coupling of ketones and hydrazones is reported. These reactions proceed through neutral ketyl radical intermediates generated via a concerted proton-coupled electron transfer (PCET) event jointly mediated by a chiral phosphoric acid catalyst and the photoredox catalyst Ir(ppy)2(dtbpy)PF6. Remarkably, these neutral ketyl radicals appear to remain H-bonded to the chiral conjugate base of the Brønsted acid during the course of a subsequent C-C bond-forming step, furnishing syn 1,2-amino alcohol derivatives with excellent levels of diastereo- and enantioselectivity. This work provides the first demonstration of the feasibility and potential benefits of concerted PCET activation in asymmetric catalysis.

Published

2013

3. Olefin Hydroaryloxylation Catalyzed by Pincer–Iridium Complexes

Author

Karsten Krogh-Jespersen, David Y. Wang, Bo Li, Michael C. Haibach, Alan S. Goldman, Andrew M. Steffens, Nicholas Lease, and Changjian Guan

Subjects

Olefin fiber, Aryl, Regioselectivity, Ether, General Chemistry, Biochemistry, Catalysis, Reductive elimination, Pincer movement, Williamson ether synthesis, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Organic chemistry

Abstract

Aryl alkyl ethers, which are widely used throughout the chemical industry, are typically produced via the Williamson ether synthesis. Olefin hydroaryloxylation potentially offers a much more atom-economical alternative. Known acidic catalysts for hydroaryloxylation, however, afford very poor selectivity. We report the organometallic-catalyzed intermolecular hydroaryloxylation of unactivated olefins by iridium "pincer" complexes. These catalysts do not operate via the hidden Brønsted acid pathway common to previously developed transition-metal-based catalysts. The reaction is proposed to proceed via olefin insertion into an iridium-alkoxide bond, followed by rate-determining C-H reductive elimination to yield the ether product. The reaction is highly chemo- and regioselective and offers a new approach to the atom-economical synthesis of industrially important ethers and, potentially, a wide range of other oxygenates.

Published

2013

4. Cleavage of Ether, Ester, and Tosylate C(sp3)–O Bonds by an Iridium Complex, Initiated by Oxidative Addition of C–H Bonds. Experimental and Computational Studies

Author

Jongwook Choi, Karsten Krogh-Jespersen, David Y. Wang, Sabuj Kundu, Yuriy Choliy, Thomas J. Emge, and Alan S. Goldman

Subjects

Hydride, Methyl acetate, Aryl, Thermal decomposition, chemistry.chemical_element, Ether, General Chemistry, Photochemistry, Biochemistry, Medicinal chemistry, Oxidative addition, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Iridium, Methylene

Abstract

A pincer-ligated iridium complex, (PCP)Ir (PCP = κ(3)-C6H3-2,6-[CH2P(t-Bu)2]2), is found to undergo oxidative addition of C(sp(3))-O bonds of methyl esters (CH3-O2CR'), methyl tosylate (CH3-OTs), and certain electron-poor methyl aryl ethers (CH3-OAr). DFT calculations and mechanistic studies indicate that the reactions proceed via oxidative addition of C-H bonds followed by oxygenate migration, rather than by direct C-O addition. Thus, methyl aryl ethers react via addition of the methoxy C-H bond, followed by α-aryloxide migration to give cis-(PCP)Ir(H)(CH2)(OAr), followed by iridium-to-methylidene hydride migration to give (PCP)Ir(CH3)(OAr). Methyl acetate undergoes C-H bond addition at the carbomethoxy group to give (PCP)Ir(H)[κ(2)-CH2OC(O)Me] which then affords (PCP-CH2)Ir(H)(κ(2)-O2CMe) (6-Me) in which the methoxy C-O bond has been cleaved, and the methylene derived from the methoxy group has migrated into the PCP Cipso-Ir bond. Thermolysis of 6-Me ultimately gives (PCP)Ir(CH3)(κ(2)-O2CR), the net product of methoxy group C-O oxidative addition. Reaction of (PCP)Ir with species of the type ROAr, RO2CMe or ROTs, where R possesses β-C-H bonds (e.g., R = ethyl or isopropyl), results in formation of (PCP)Ir(H)(OAr), (PCP)Ir(H)(O2CMe), or (PCP)Ir(H)(OTs), respectively, along with the corresponding olefin or (PCP)Ir(olefin) complex. Like the C-O bond oxidative additions, these reactions also proceed via initial activation of a C-H bond; in this case, C-H addition at the β-position is followed by β-migration of the aryloxide, carboxylate, or tosylate group. Calculations indicate that the β-migration of the carboxylate group proceeds via an unusual six-membered cyclic transition state in which the alkoxy C-O bond is cleaved with no direct participation by the iridium center.

Published

2013

5. Olefin Isomerization by Iridium Pincer Catalysts. Experimental Evidence for an η3-Allyl Pathway and an Unconventional Mechanism Predicted by DFT Calculations

Author

David Y. Wang, Maurice Brookhart, Karsten Krogh-Jespersen, Yuriy Choliy, Soumik Biswas, Alan S. Goldman, and Zheng Huang

Subjects

chemistry.chemical_classification, Allylic rearrangement, Olefin fiber, Double bond, Hydride, chemistry.chemical_element, General Chemistry, Photochemistry, Biochemistry, Medicinal chemistry, Catalysis, Pincer movement, POCOP, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Iridium, Isomerization

Abstract

The isomerization of olefins by complexes of the pincer-ligated iridium species ((tBu)PCP)Ir ((tBu)PCP = κ(3)-C(6)H(3)-2,6-(CH(2)P(t)Bu(2))(2)) and ((tBu)POCOP)Ir ((tBu)POCOP = κ(3)-C(6)H(3)-2,6-(OP(t)Bu(2))(2)) has been investigated by computational and experimental methods. The corresponding dihydrides, (pincer)IrH(2), are known to hydrogenate olefins via initial Ir-H addition across the double bond. Such an addition is also the initial step in the mechanism most widely proposed for olefin isomerization (the "hydride addition pathway"); however, the results of kinetics experiments and DFT calculations (using both M06 and PBE functionals) indicate that this is not the operative pathway for isomerization in this case. Instead, (pincer)Ir(η(2)-olefin) species undergo isomerization via the formation of (pincer)Ir(η(3)-allyl)(H) intermediates; one example of such a species, ((tBu)POCOP)Ir(η(3)-propenyl)(H), was independently generated, spectroscopically characterized, and observed to convert to ((tBu)POCOP)Ir(η(2)-propene). Surprisingly, the DFT calculations indicate that the conversion of the η(2)-olefin complex to the η(3)-allyl hydride takes place via initial dissociation of the Ir-olefin π-bond to give a σ-complex of the allylic C-H bond; this intermediate then undergoes C-H bond oxidative cleavage to give an iridium η(1)-allyl hydride which "closes" to give the η(3)-allyl hydride. Subsequently, the η(3)-allyl group "opens" in the opposite sense to give a new η(1)-allyl (thus completing what is formally a 1,3 shift of Ir), which undergoes C-H elimination and π-coordination to give a coordinated olefin that has undergone double-bond migration.

Published

2012