Gold(I)‐Catalyzed Diazo Cross‐Coupling: A Selective and Ligand‐Controlled Denitrogenation/Cyclization Cascade

An unprecedented gold‐catalyzed ligand‐controlled cross‐coupling of diazo compounds by sequential selective denitrogenation and cyclization affords N‐substituted pyrazoles in a position‐switchable mode. This novel transformation features selective decomposition of one diazo moiety and simultaneous preservation of the other one from two substrates. Notably, the choice of the ancillary ligand to the gold complex plays a pivotal role on the chemo‐ and regioselectivity of the reactions.     

Gold(I)‐Catalyzed Diazo Coupling: Strategy towards Alkene Formation and Tandem Benzannulation

A gold(I)‐catalyzed cross‐coupling of diazo compounds to afford tetrasubstituted alkenes has been developed by taking advantage of a trivial electronic difference between two diazo substrates. A N‐heterocyclic‐carbene‐derived gold complex is the most effective catalyst for this transformation. Based on this new strategy, a gold(I)‐initiated benzannulation has been achieved through a tandem reaction involving a diazo cross‐coupling, 6π electrocyclization, and oxidative aromatization.     

Mechanisms of phosphine‐catalyzed [4 + 3] annulation of allenoates with C,N‐cyclic azomethine imines: A DFT investigation

In this article, mechanisms of phosphine‐catalyzed [4 + 3] annulation of allenoates with C, N‐cyclic azomethine imines have been investigated using density functional theory. The catalytic cycle for the title reaction consists of five steps. Namely, the first step is the nucleophilic addition of phosphine catalyst, the second one is the C C bond formation, the third one is the proton transfer process, and the next one is the ring‐closure process, the last one is dissociation of the catalyst and the product generation. The calculated results indicate that the nucleophilic addition of phosphine catalyst is rate‐determining. With the use of Cat as the chiral catalyst, optically active products were obtained in good yields with excellent enantioselectivities while the C C bond formation is stereoselectivity‐determining. Furthermore, the theoretically predicted the main product is SS configuration, which is in good agreement with the experimental results. The special role of the catalysts and origin of stereoselectivity was also identified by NBO, GRI, and FMO analyses. This work might be helpful for understanding the significant roles of phosphine catalyst and thus provide valuable insights on the rational design of potential catalysts for this kind of reactions.     

Mechanistic analysis of iridium(III) catalyzed direct C-H arylations: a DFT study

In a recent experimental work the Ir complex [Ir(cod)(py)(PCy(3))](PF(6)) (that is, Crabtree's catalyst) has been shown to catalyze the C-H arylation of electron-rich heteroarenes with iodoarenes using Ag(2)CO(3) as base. For this process, an electrophilic metalation mechanism, (S(E)Ar) has been proposed as operative mechanism rather than the concerted metalation-deprotonation (CMD) mechanism, widely implicated in Pd-catalyzed arylation reactions. Herein we have investigated the C-H activation step for several (hetero)arenes catalyzed by a Ir(III) catalyst and compared the data obtained with the results for the Pd(II)-catalyzed C-H bond activation. The calculations demonstrate that, similar to Pd(II)-catalyzed reactions, the Ir(III)-catalyzed direct C-H arylation occurs through the CMD pathway which accounts for the experimentally observed regioselectivity. The transition states for Ir(III)-catalyzed direct C-H arylation feature stronger metal-C((arene)) interactions than those for Pd(II)-catalyzed C-H arylation. The calculations also demonstrate that ligands with low trans effect may decrease the activation barrier of the C-H bond cleavage.     

A theoretical study of imine hydrocyanation catalyzed by halogen‐bonding

A detailed theoretical study of the mechanism and energetics of an organocatalysis based on C?N activation by halogen‐bonding is presented for the hydrocyanation of N‐benzylidenemethylamine. The calculations at the level of scalar‐relativistic gradient‐corrected density functional theory give an insight in this catalytic concept and provide information on the characteristics of four different monodentate catalyst candidates acting as halogen‐bond donors during the reaction. © 2015 Wiley Periodicals, Inc.     

Gas‐phase pyrolysis mechanisms of 3‐anilino‐1‐propanol: Density functional theory study

The gas‐phase pyrolytic decomposition mechanisms of 3‐anilino‐1‐propanol with the products of aniline, ethylene, and formaldehyde or N‐methyl aniline and aldehyde were studied by density functional theory. The geometries of the reactant, transition states, and intermediates were optimized at the B3LYP/6‐31G (d, p) level. Vibration analysis was carried out to confirm the transition state structures, and the intrinsic reaction coordinate method was performed to search the minimum energy path. Four possible reaction channels are shown, including two concerted reactions of direct pyrolytic decomposition and two indirect channels in which the reactant first becomes a ring‐like intermediate, followed by concerted pyrogenation. One of the concerted reactions in the direct pyrolytic decomposition has the lowest activation barrier among all the four channels, and so, it occurs more often than others. The results appear to be consistent with the experimental outcomes. © 2008 Wiley Periodicals, Inc. Int J Quantum Chem, 2009     

Trifluoromethylthiolation of Aryl Iodides and Bromides Enabled by a Bench‐Stable and Easy‐To‐Recover Dinuclear Palladium(I) Catalyst

While palladium catalysis is ubiquitous in modern chemical research, the recovery of the active transition‐metal complex under routine laboratory applications is frequently challenging. Described herein is the concept of alternative cross‐coupling cycles with a more robust (air‐, moisture‐, and thermally‐stable) dinuclear Pd^I complex, thus avoiding the handling of sensitive Pd⁰ species or ligands. Highly efficient C? SCF₃ coupling of a range of aryl iodides and bromides was achieved, and the recovery of the Pd^I complex was accomplished via simple open‐atmosphere column chromatography. Kinetic and computational data support the feasibility of dinuclear Pd^I catalysis. A novel SCF₃‐bridged Pd^I dimer was isolated, characterized by X‐ray crystallography, and verified to be a competent catalytic intermediate.     

Theoretical investigation on the dissociation of (R)‐benzoin catalyzed by benzaldehyde lyase

Benzaldehyde lyase (BAL) is a versatile thiamin diphosphate (THDP)‐dependent enzyme with widespread synthetic applications in industry. Besides lyase activity, BAL also performs the functions as carboligase and decarboxylase. Unlike many other THDP‐dependent enzymes, the active center of BAL is devoid of any acid‐base amino acid residues except Glu50 and His29, and therefore, the catalytic mechanism of BAL is unusual. In this article, the dissociation mechanism of (R)‐benzoin to benzaldehyde catalyzed by BAL has been studied by using density functional theory method. The calculation results indicate that the whole reaction consists of four elementary steps, and at least two steps contribute to rate‐limiting. A big difference with other THDP‐dependent enzymes is that, in the first stage of the reaction, the ligation of substrate and THDP ylide is not companied by proton transfer, and in the subsequent transition states and intermediates, the carbonyl oxygen always exists in the form of anion. Gln113, His29, and 4′‐amino group of THDP are found to have the function to stabilize the transition states and intermediates. His29 acts as the proton acceptor in step 2 and proton donor in step 3 using one water molecule as mediator. © 2013 Wiley Periodicals, Inc.     

Synthesis of Aryldiazoacetates through Palladium(0)‐Catalyzed Deacylative Cross‐Coupling of Aryl Iodides with Acyldiazoacetates

Palladium(0)‐catalyzed deacylative cross‐coupling of aryl iodides and acyldiazocarbonyl compounds can be achieved at room temperature under mild reaction conditions. The coupling reaction represents a highly efficient and general method for the synthesis of aryldiazocarbonyl compounds, which have found wide and increasing applications as precursors for generating donor/acceptor‐substituted metallocarbenes.     

A DFT study on the mechanisms for the cycloaddition reactions between 1‐Aza‐2‐azoniaallene cations and carbodiimides

The mechanisms of the title reactions between 1‐aza‐2‐azoniaallene cations and carbodiimides in the gas phase have been examined using the Becke‐3‐parameter‐Lee‐Yang‐Parr (B3LYP) at 6‐31++G** level. The theoretical results revealed that the reaction is a domino reaction that comprises two consecutive reactions: an ionic [3+2] cycloaddition reaction between 1‐aza‐2‐azoniallene cation and carbodiimide to yield the cycloadduct 3 and then a [1,2]‐shift to yield the thermodynamically more stable adduct 4 . Both stepwise and concerted pathways are accessible in the first cycloaddition in the model reaction. The activation barriers of them are almost equivalent. For the [1,2]‐shift reactions, both of the electron‐withdrawing chlorine substituent and the electron‐releasing methyl substituent on the 1‐aza‐2‐azoniaallene cation can facilitate the reaction but have little effects when substituted in the carbodiimide moiety. The model reaction has also been investigated at the QCISD (quadratic configuration interaction using single and double substitutions)/6‐31++G** and CCSD(T) (coupled cluster calculations with single and double excitations and a perturbative estimate of triple contributions calculations)/6‐31++G** levels as well as by the density functional theory. In addition, solvent effects with the isodensity‐surface polarized continuum model are also reported for all the reactions. In solvent dichloromethane, the cycloadducts of all the reactions, except model reaction and reaction d, were obtained from reactants directly as the result of the solvent effect. © 2011 Wiley Periodicals, Inc. Int J Quantum Chem, 2011     

A DFT study on the insertion of CO2 into styrene oxide catalyzed by 1‐butyl‐3‐methyl‐Imidazolium bromide ionic liquid

Green systems able to capture or fix CO₂ are becoming more important specially to reduce environmental impacts. In this work, the mechanism of insertion of CO₂ into styrene oxide (STYO) both in the absence and presence of the catalyst 1‐butyl‐3‐methyl‐imidazolium bromide (BMIm Br) was investigated through calculations based on density functional theory in the ωB97X‐D level. Two different routes were considered and it was shown they are energetically available and compete against each other. For both routes, the rate‐determinant step is the ring opening of STYO resulting from the nucleophilic attack of the Br^? on the C atom from STYO and is associated mainly to the participation of the cation and the anion from the catalyst in the reaction. Reactive indices and noncovalent interaction analysis were used as a tool to investigate this reason. This work allowed a better comprehension of the underlying mechanism and the supplied data provide valuable support for the design of new more efficient ionic liquid catalyst. © 2015 Wiley Periodicals, Inc.     

Heck‐Type Reactions of Imine Derivatives: A DFT Study

The mechanism of a recently discovered intramolecular Heck‐type coupling of oximes with aryl halides (Angew. Chem. Int. Ed. 2007 , 46, 6325) was systematically studied by using density functional methods enhanced with a polarized continuum solvation model. The overall catalytic cycle of the reaction was found to consist of four steps: oxidative addition, migratory insertion, β‐H elimination, and catalyst regeneration, whereas an alternative base‐promoted C? H activation pathway was determined to be less favorable. Migratory insertion was found to be the rate determining step in the catalytic cycle. The apparent activation barrier of migratory insertion of the (E)‐oxime was +20.5 kcal mol^?1, whereas the barrier of (Z)‐oxime was as high as +32.7 kcal mol^?1. However, (Z)‐oxime could isomerize to form the more active (E)‐oxime with the assistance of K₂CO₃, so that both the (E)‐ and (Z)‐oxime substrates could be transformed to the desired product. Our calculations also indicated that the Z product was predominant in the equilibrium of the isomerization of the imine double bond, which constituted the reason for the good Z‐selectivity observed for the reaction. Furthermore, we examined the difference between the intermolecular Heck‐type reactions of imines and of olefins. It was found that in the intermolecular Heck‐type coupling of imines, the apparent activation barrier of migratory insertion was as high as +35 kcal mol^?1, which should be the main obstacle of the reaction. The analysis also revealed the main problem for the intermolecular Heck‐type reactions of imines, which was that the breaking of a C?N π bond was much more difficult than the breaking of a C?C π bond. After systematic examination of a series of substituted imines, (Z)‐N‐amino imine and N‐acetyl imine were found to have relatively low barriers of migratory insertion, so that they might be possible substrates for intermolecular Heck‐type coupling.     

Mechanism of Gold(I)‐Catalyzed Conia‐ene Reaction of β‐Ketoesters with Alkynes: A DFT Study

Density functional calculations have been performed to comparatively investigate two possible pathways of Au(I)‐catalyzed Conia‐ene reaction of β‐ketoesters with alkynes. Our studies find that, under the assistance of trifluoromethanesulfonate (TfO), the β‐ketoester is the most likely to undergo Model II to isomerize into its enol form, in which TfO plays a proton transfer role through a 6‐membered ring transition state. The coordination of the Au(I) catalyst to the alkynes triple bond can enhance the eletrophilic capability and reaction activity of the alkynes moiety, which triggers the nucleophilic addition of the enol moiety on the alkynes moiety to give a vinyl‐Au intermediate. This cycloisomerizaion step is exothermal by 21.3 kJ/mol with an energy barrier of 56.0 kJ/mol. In the whole catalytic process, the protonation of vinyl‐Au is almost spontaneous, and the formation of enol is a rate‐limiting step. The generation of enol and the activation of Au(I) catalyst on the alkynes are the key reasons why the Conia‐ene reaction can occur in mild condition. These calculations support that Au(I)‐catalyzed Conia‐ene reactions of β‐ketoesters with alkynes go through the pathway 2 proposed by Toste.     

DFT studies on the mechanism of Ag2CO3‐catalyzed hydroazidation of unactivated terminal alkynes with TMS‐N3: An insight into the silver(I) activation mode

Silver‐mediated hydroazidation of unactivated alkynes has been developed as a new method for the synthesis of vinyl azides. Density functional theory calculations toward this reaction reveal that terminal alkynes with TMS‐N₃ participated hydroazidation proceed through HN₃ formation, deprotonation and silver acetylides formation, nucleophilic addition, and protonation of terminal carbon by AgHCO₃. It is also found that water molecules and activation modes of Ag (I) have a significant influence on the title reaction mechanism. Initially, catalyst Ag₂CO₃ coordinates preferentially with internal N atom of TMS–N₃ to assist water as hydrogen source and proton‐shuttle in facilitating HN₃ formation. Then, the regioselective anti‐addition of HN₃ to triple bond of active silver‐acetylide or ethynyl carbinols affords product vinyl azide via Ag–C σ‐bond activation or Ag…C π‐coordination activation modes, and the former one is more favorable. The origin of the difference regioselectivity is ascribed to the electronic and orbital effects of the reactive sites. Moreover, Ag₂CO₃ is the critical catalyst, acting as activator, base, and stabilizer to promote the HN₃ and vinyl azide formation. Water molecule plays an important role as proton shuttle to promote HN₃ and key active silver acetylides formation, thus improving the yield of product. © 2017 Wiley Periodicals, Inc.     

Refractive indices of organo‐metallic and ‐metalloid compounds: A long‐range corrected DFT study

Refractive indices of metal‐ and metalloid‐containing compounds are systematically evaluated using the Lorentz–Lorenz equation with polarizabilities obtained via density functional theory (DFT). Among exchange‐correlation functionals studied, the long‐range corrected (LC) fuctionals yield the lowest errors for the polarizabilities of gaseous compounds and refractive indices of liquids. The LC‐DFT predicts very well the wavelength dependence of refractive indices. A scheme for computing Abbe numbers of organometallic and organometaloid compounds is proposed and a refractive index – Abbe number plot for 80 compounds is constructed. The compounds containing heavier metals tend to have higher refractive index and lower Abbe number, but several outliers, among them Te(CH₃)₂, Ni(PF₃)₄, Sb(C₂F₃)₃, Hg(C₂F₃)₂, are found. For Hg(C₂F₃)₂, also the effect of intramolecular and intermolecular degrees of freedom on polarizability is investigated. The absolute relative error in polarizability decreases from 5.7% for monomer model to 1.7% when a dimer model (derived from the available experimental crystal data) is employed. © 2016 Wiley Periodicals, Inc.     

Copper‐catalyzed C(sp2)–C(sp) Sonogashira‐type cross‐coupling reactions accelerated by polycyclic aromatic hydrocarbons

Copper‐catalyzed Sonogashira‐type reactions were dramatically accelerated by introducing a catalytic amount of polycyclic aromatic hydrocarbon additive. This novel catalytic system features low copper loading (0.5 mol% < Cu < 5 mol%), broad reaction scope and remarkable substrate tolerance. Both aromatic and aliphatic terminal alkynes as well as diverse aryl iodides were employed in this transformation, affording respectable yields of the desired products. The novel Cu(OTf)₂/pyrene system was subsequently employed to synthesize phenylacetylene‐based fluorescent compounds. Copyright © 2015 John Wiley & Sons, Ltd.