Your search keyword '"Lan, Yu"' showing total 7 results

1. Chiral Phosphoric Acid Catalyzed Conversion of Epoxides into Thiiranes: Mechanism, Stereochemical Model, and New Catalyst Design.

Author

Duan, Meng, Díaz‐Oviedo, Christian David, Zhou, Yang, Chen, Xiangyang, Yu, Peiyuan, List, Benjamin, Houk, Kendall N., and Lan, Yu

Subjects

PHOSPHORIC acid, EPOXY compounds, DENSITY functional theory, SULFURATION, CATALYSTS

Abstract

Computations and experiments leading to new chiral phosphoric acids (CPAs) for epoxide thionations are reported. Density functional theory calculations reveal the mechanism and origin of the enantioselectivity of such CPA‐catalyzed epoxide thionations. The calculated mechanistic information was used to design new efficient CPAs that were tested experimentally and found to be highly effective. Bulky ortho‐substituents on the 3,3′‐aryl groups of the CPA are important to restrict the position of the epoxide in the key transition states for the enantioselectivity‐determining step. Larger para‐substituents significantly improve the enantioselectivity of the reaction. [ABSTRACT FROM AUTHOR]

Published

2022

2. Mechanism of Palladium‐Catalyzed Spiroannulation of Naphthols with Alkynes: A Density Functional Theory Study.

Author

Luo, Xiaoling, Zhong, Kangbao, and Lan, Yu

Subjects

DENSITY functional theory, ALKYNES, OXIDATIVE addition, ARYL bromides, MOIETIES (Chemistry), AROMATIZATION

Abstract

Pd‐catalyzed spiroannulation of bromophenylnaphthalenols with acetylenes to achieve asymmetric dearomatization is a powerful way to construct chiral spiro‐compounds. DFT calculations with the M06 functional have been performed to reveal the mechanism and enantioselectivity of this reaction. After reversible oxidative addition of aryl bromide to Pd(0), acetylene insertion into the Pd−C(aryl) bond is considered to be the rate‐ and enantioselectivity determining step. Subsequent deprotonation and reductive elimination then give the spiroannulation product. The overlay and noncovalent interaction analysis of the critical transition states were used to reveal the origin of the enantioselectivity for this reaction. We found that the axial chirality of the naphthol moiety affects the relative free energies of the corresponding transition states, whereas the enantioselectivity is controlled by the steric repulsion between the naphthol moiety and the ligand. [ABSTRACT FROM AUTHOR]

Published

2020

3. Origin of Regio‐ and Stereoselectivity in the NHC‐catalyzed Reaction of Alkyl Pyridinium with Aliphatic Enal.

Author

Wang, Yang, Qu, Ling‐Bo, Lan, Yu, and Wei, Donghui

Subjects

STEREOSELECTIVE reactions, DENSITY functional theory

Abstract

The mechanisms of N‐heterocyclic carbene (NHC)‐catalyzed dearomatization reaction of alkyl pyridinium have been intensively studied using the density functional theory (DFT) method. The chemoselectivity and stereoselectivity were both analyzed based on the established mechanisms. The computational results showed that the chemoselective C4‐addition occurred before the C2‐addition, which is mainly because the C4 atom was more reactive according to the local reactivity analysis. The stereoselectivity was also investigated, and the C−C bond formation step was identified as the stereoselectivity‐determining step. The C−H⋅⋅⋅F and O−H⋅⋅⋅N interactions are identified as the main factors that govern the stereoselectivity by NCI analysis, and the preferred product was the RS‐configuration. This theoretical investigation would provide a case for understanding and predicting the selectivity of the organocatalytic dearomatization reactions of alkyl pyridinium. [ABSTRACT FROM AUTHOR]

Published

2020

4. Investigating the Mechanism of Palladium‐Catalyzed Radical Oxidative C(sp3)−H Carbonylation: A DFT Study.

Author

Xiong, Qin, Xu, Dongdong, Shan, Chunhui, Liu, Song, Luo, Yixin, Liu, Fenru, Liu, Shihan, Lan, Yu, and Bai, Ruopeng

Subjects

PALLADIUM catalysts, ALKANES, CARBONYLATION, CARBON-hydrogen bonds, DENSITY functional theory, OXIDATION

Abstract

Palladium (Pd)‐catalyzed radical oxidative C−H carbonylation of alkanes is a useful method for functionalizing hydrocarbons, but there is still a lack of understanding of the mechanism, which restricts the application of this reaction. In this work, density functional theory (DFT) calculations were carried out to study the mechanism for a Pd‐catalyzed radical esterification reaction. Two plausible reaction pathways have been proposed and validated by DFT calculations. The computational results reveal that the generated alkyl radical prefers to add to the carbon monoxide (CO) molecule to form a carbonyl radical before bonding with the Pd species. Radical addition onto Pd followed by CO migratory insertion was unfavorable owing to the high energy barrier of the migratory insertion step. The regioselectivity of the C(sp3)−H carbonylation was also investigated by DFT. The results show that the regioselectivity is controlled by both the bond dissociation energy of the reacting C−H bond and the stability of the corresponding generated carbon radical. Competitive side reactions also affected the yield and regioselectivity owing to the rapid consumption of the stable radical intermediate. Carbonylation mechanism: DFT method M06‐L was used to investigate the mechanism of Pd‐catalyzed radical oxidative carbonylation of alkanes with alcohols to afford alkyl acid esters. The results show alkyl radicals prefer to add to the CO molecule to form a carbonyl radical before bonding with the Pd species. Regioselectivity is controlled by both the bond dissociation energy of reacting the C−H bond and the stability of the corresponding generated carbon radical. [ABSTRACT FROM AUTHOR]

Published

2019

5. Mechanistic Insight into Palladium‐Catalyzed Carbocyclization‐Functionalization of Bisallene: A Computational Study.

Author

Zhang, Jing, Lv, Kang, Liu, Tao, Shan, Chunhui, Zhu, Lei, Lan, Yu, and Li, Yuanyuan

Subjects

PALLADIUM catalysts, RING formation (Chemistry), ALLENE, DENSITY functional theory, COMPUTATIONAL chemistry, REGIOSELECTIVITY (Chemistry)

Abstract

Density functional theory calculations were performed to reveal the mechanisms of Pd‐catalyzed cascade carbocyclization‐borylation and arylation reactions. The computational results indicate that the reactions start with allylic C−H cleavage through concerted metalation‐deprotonation and an intramolecular exo‐type allene insertion to form a six‐membered carbocycle intermediate. The regioselectivity of insertion could be explained by frontier molecular orbital theory and natural population analysis calculation. In the absence of extra nucleophiles, η1/η3‐isomerization followed by acetate‐assisted deprotonation could yield polyene product. When nucleophile was added to the reaction system, transmetalation and subsequent reductive elimination could give the exo‐substituted triene as major product. Meanwhile, η1/η3‐isomerization, transmetalation, and reductive elimination could afford the endo‐isomer as side product. The regioselectivity of further functionalization is controlled by the competition of transmetalation and η1/η3‐isomerization. The computational results show that both exo‐ and endo‐boronation product could be observed when bis(pinacolato)diboron is added as nucleophile. However, only exo‐phenylation product is observed when phenylboronic acid is used as nucleophile because of the high free‐energy barrier for reductive elimination from aryl η3‐allylic palladium. Show me the way: DFT calculations were employed to study the mechanism and origin of regioselectivity of cascade carbocyclization‐functionalization reactions. [ABSTRACT FROM AUTHOR]

Published

2019

6. Mechanistic Insights into Manganese (I)‐Catalyzed Chemoselective Hydroarylations of Alkynes: A Theoretical Study.

Author

Wang, Zheyuan, Zhu, Lei, Zhong, Kangbao, Qu, Ling‐Bo, Bai, Ruopeng, and Lan, Yu

Subjects

MANGANESE catalysts, CATALYSIS, AROMATIZATION, PROTON transfer reactions, CHEMOSELECTIVITY, DENSITY functional theory

Abstract

Density functional theory calculations were employed to elucidate the mechanism of Mn‐catalyzed chemoselective hydroarylation reactions. The Mn‐catalyzed [4+2] annulation undergoes a reaction pathway involving sequential imine‐directed C−H bond cleavage, alkyne insertion into the Mn−C bond, β‐oxygen elimination and outer catalytic cycle annulation–aromatization. Computational results demonstrated that the previously proposed chelation‐assisted alkyne insertion process was unfavorable owing to the weak coordination ability of the β‐oxygen leaving group compared with that of CO. Further noncovalent interactions analysis indicated that the origin of the high regioselectivity was contributed to the steric repulsion resulting from significant nonbonding overlap between the reacting aryl moiety and the quaternary carbon group of the reactant in the alkyne insertion step. In addition, in the Brønsted‐acid‐mediated chemoselective alkenylation reaction, the used terminal alkynes had relatively enhanced reactivity in the alkyne insertion step owing to its reduced steric repulsion. From the active alkenyl‐Mn intermediate, the activation free energy of protonation and β‐oxygen elimination are approximate, thus the alkenylated product is obtained after protonation in an acidic system. We expect that this detailed mechanistic study will significantly enhance our ability to develop Mn‐catalyzed arene C−H bond functionalization reactions. Clarity, form, and function: Density functional theory calculations were employed to elucidate the mechanism of Mn‐catalyzed chemoselective hydroarylation reactions. The Mn‐catalyzed [4+2] annulation undergoes a reaction pathway involving sequential imine‐directed C−H bond cleavage, alkyne insertion into the Mn−C bond, β‐oxygen elimination and outer catalytic cycle annulation–aromatization. [ABSTRACT FROM AUTHOR]

Published

2018

7. Mechanism of Ir-catalyzed hydrogenation: A theoretical view.

Author

Cui, Cheng-Xing, Chen, Haohua, Li, Shi-Jun, Zhang, Tao, Qu, Ling-Bo, and Lan, Yu

Subjects

*HYDROGENATION, *OXIDATIVE addition, *DENSITY functional theory, *REACTION mechanisms (Chemistry), *STEREOCHEMISTRY

Abstract

Ir-catalysis has been widely adopted in hydrogenation reactions for the transformation of unsaturated molecules to the corresponding saturated ones. We reviewed herein the DFT studies on mechanism of Ir-catalyzed homogeneous hydrogenations with respect to various hydrogen sources. Moreover, the stereochemistry and substituent effects in the Ir-catalyzed hydrogenations are considered. • Mechanistic studies towards Ir-mediated hydrogenation were summarized in this review. • General catalytic cycles given by theoretical studies are involved in each example. • Mechanism discussions are classified according to the substrates. • The understanding of mechanism would be helpful for further design new Ir-catalysis. Ir catalysis is widely used in hydrogenation reactions to transform unsaturated molecules to the corresponding saturated molecules. Understanding the reaction mechanism is helpful for design of new Ir-catalyzed hydrogenation reactions, as well as for controlling the regio/stereoselectivity. Density functional theory is a powerful tool for mechanistic study of organometallic catalysis, and it has been widely used to reveal the reaction pathways in this research area. With the development of computational methods, much progress has recently been made in mechanistic study of Ir-catalyzed hydrogenation reactions. Herein, we present a review of theoretical studies of the mechanism of Ir-catalyzed homogeneous hydrogenation. A redox pathway is commonly proposed for hydrogenation of non-polar unsaturated bonds, which involves oxidative addition of a hydrogen molecule to afford a high valence Ir hydride complex, insertion of an unsaturated bond into the Ir–H bond, and reductive elimination. Alternatively, the dihydrogen molecule can undergo a heterolysis reaction to provide a formal hydride ion and a proton. Subsequent nucleophilic and electrophilic attack can then also achieve hydrogenation of the polar unsaturated bond. In this review, the studies of the mechanism of Ir-catalyzed hydrogenation are classified according to the type of substrate: olefins, carbonyls, and imines. In each category, the reactions are discussed with respect to the various hydrogen sources. The stereochemistry and substituent effect in Ir-catalyzed hydrogenation are also considered. [ABSTRACT FROM AUTHOR]

Published

2020