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Shaofa Sun

Bio: Shaofa Sun is an academic researcher from Hubei University. The author has contributed to research in topics: Cycloaddition & Annulation. The author has an hindex of 14, co-authored 56 publications receiving 538 citations.


Papers
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Journal ArticleDOI
TL;DR: In this paper, an enamine catalyzed strategy was proposed to fully promote a 1,3-dipolar cycloaddition to access a vast pool of substituted 1,2,3 triazoles with water as the only solvent.

106 citations

Journal ArticleDOI
TL;DR: In this article, an efficient synthesis of highly substituted pyrroles was developed using a Pd-catalyzed oxidative reaction of 4-aminocoumarins with internal alkynes.
Abstract: An efficient synthesis of highly substituted pyrroles is developed using a Pd-catalyzed oxidative reaction of 4-aminocoumarins with internal alkynes.

42 citations

Journal ArticleDOI
TL;DR: In this paper, an efficient synthesis of functionalized 1,3-dihydro-2H-pyrrol-2-one was developed based on a [3+2] cycloaddition reaction of aza-oxyallylic cations and alkynes.

36 citations

Journal ArticleDOI
TL;DR: An efficient and convenient double decarboxylation process is documented for the synthesis of 4-substituted 3,4-dihydrocoumarin in moderate to excellent yields under mild reaction conditions (up to 98%).
Abstract: 3,4-Dihydrocoumarins, considered to be valuable building blocks, have attracted considerable attention due to their various biological activities. Herein, we have documented an efficient and convenient double decarboxylation process for the synthesis of 4-substituted 3,4-dihydrocoumarin in moderate to excellent yields under mild reaction conditions (up to 98%).

33 citations

Journal ArticleDOI
TL;DR: Optically active 3,3-disubstituted oxindoles were obtained by a new organocatalyzed aerobic oxidative method as discussed by the authors, which was used to extract oxindole oxides.
Abstract: Optically active 3,3-disubstituted oxindoles are obtained by a new organocatalyzed aerobic oxidative method.

28 citations


Cited by
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Journal ArticleDOI
TL;DR: The intention of this review is to provide a detailed analysis of the various supramolecular interactions of triazoles in comparison to established functional units, which may serve as guidelines for further applications.
Abstract: The research on 1,2,3-triazoles has been lively and ever-growing since its stimulation by the advent of click chemistry The attractiveness of 1H-1,2,3-triazoles and their derivatives originates from their unique combination of facile accessibility via click chemistry and truly diverse supramolecular interactions, which enabled myriads of applications in supramolecular and coordination chemistry The nitrogen-rich triazole features a highly polarized carbon atom allowing the complexation of anions by hydrogen and halogen bonding or, in the case of the triazolium salts, via charge-assisted hydrogen and halogen bonds On the other hand, the triazole offers several N-coordination modes including coordination via anionic and cationic nitrogen donors of triazolate and triazolium ions, respectively After CH-deprotonation of the triazole and the triazolium, powerful carbanionic and mesoionic carbene donors, respectively, are available The latter coordination mode even features non-innocent ligand behavior Moreover, these supramolecular interactions can be combined, eg, in ion-pair recognition, preorganization by intramolecular hydrogen bond donation and acceptance, and in bimetallic complexes Ultimately, by clicking two building blocks into place, the triazole emerges as a most versatile functional unit allowing very successful applications, eg, in anion recognition, catalysis, and photochemistry, thus going far beyond the original purpose of click chemistry It is the intention of this review to provide a detailed analysis of the various supramolecular interactions of triazoles in comparison to established functional units, which may serve as guidelines for further applications

626 citations

Journal ArticleDOI
TL;DR: In this paper, the development of catalytic systems in water in the presence of micelles obtained by addition of surfactants, focusing on the effects of these simple, economic, and green reaction media on important aspects like recyclability, activity, product and substrate selectivity.

414 citations

01 Jun 2011
TL;DR: This work hypothesized that a similar Pd-based system might allow for the formation of an aromatic C–SCF3 bond after the successful coupling of weak nucleophiles traditionally thought to be reluctant participants in the transmetalation or reductive elimination steps of a typical Pd(0)/Pd(II) catalytic cycle.
Abstract: The unique chemical properties of aryl trifluoromethyl sulfides (ArSCF3) have been known for over 60 years.[1] The capacity of SCF3 to act as a lipophilic electron-withdrawing group has resulted in the incorporation of ArSCF3 components into a number of pharmaceutical and agrochemical agents.[2] Unfortunately, direct access to this important class of compounds is complicated by a lack of efficient, safe and general methods.[1a, 3] Significant advances in Pd-catalyzed cross-coupling processes have allowed for efficient access to a diverse array of functionalized aromatic products, including aryl sulfides.[4] While the coupling of many aromatic or aliphatic thiols with aryl halides has been achieved with very high efficiency,[5] the analogous transformation to form aryl trifluoromethyl sulfides has not been reported. As gaseous CF3SH (b.p. = -36 °C)[6] can be difficult to handle in a laboratory setting, several SCF3 salts have been developed, however, most of these decompose under standard cross-coupling conditions.[3c] It has been postulated that reductive elimination of Ar–SR from a palladium center is initiated via a nucleophilic attack on the electrophilic hydrocarbyl group by the metal-bound thiolate.[7] Thus, metal-catalyzed Ar–SCF3 coupling might be complicated by the reduced nucleophilicity of the SCF3 anion[2b] as compared to a standard thiolate. Recent reports from our group regarding novel ligands including BrettPhos (1), t-BuBrettPhos (2), XPhos (3) and 3,4,5,6-tetramethyl(t-Bu)XPhos (4) (Scheme 1), have allowed for the successful coupling of weak nucleophiles traditionally thought to be reluctant participants in the transmetalation or reductive elimination steps of a typical Pd(0)/Pd(II) catalytic cycle. Specifically, using these catalyst systems has allowed for the direct formation of diaryl ether,[8] aryl fluoride,[9] aryl trifluoromethyl,[10] and aryl nitro compounds[11] from their corresponding aryl halides or pseudo halides. In light of these results, we hypothesized that a similar Pd-based system might allow for the formation of an aromatic C–SCF3 bond. Scheme 1 Various ligands used in Pd-catalyzed cross-coupling reactions. As we suspected that reductive elimination from putative intermediate 11 would be rate limiting in any catalytic process, we began our investigation by attempting its preparation from oxidative addition complex 10 via treatment with AgSCF3 (Scheme 2). We were surprised when this procedure did not provide the expected transmetalation complex but instead led directly to the Ar–SCF3 product 12 (presumably via 11). Scheme 2 Formation of ArSCF3 via transmetalation and reductive elimination from an isolated LPdAr(Br) complex. Given this finding, we attempted to convert 4-(4-bromophenyl)morpholine to the corresponding trifluoromethyl sulfide using AgSCF3 and a catalytic quantity of 1 and (COD)Pd(CH2TMS)2 (Table 1). However, under these conditions, none of 13 was observed. We surmised that failure to observe the coupled product might be due to the inefficient transfer of ⊖SCF3 to 10 under catalytic conditions. Thus, we elected to examine the use of a number of alternative previously reported ⊖SCF3 sources (Table 1).[3c, e] Table 1 Examination of different SCF3 sources.[a] Clark’s[3d] work on the use of (Bu)4NI and AgSCF3 for SNAr reactions with aryl halides indicated to us that the addition of a quaternary ammonium salt might be beneficial. Consistent with this hypothesis, the addition of 1 equivalent of (Bu)4NI to the reaction mixture increased the yield of 13 from 0 % to 55 % (Table 1). Further examination of different ammonium salts revealed that Ph(Me)3NI was more effective than (Bu)4NI and that switching to a more soluble ammonium salt, Ph(Et)3NI, provided a nearly quantitative yield of the desired product (Table 1). Based on work done by Clark, it is presumed that the iodide anion binds to AgSCF3 in order generate an anionic “ate” complex. We hypothesize that a large diffuse cation further aids in the solubility of this complex. It is worth noting that while the use of quaternary ammonium iodides and bromides allowed for catalytic turnover, the corresponding chloride analogs were ineffective. With the optimal combination of Ph(Et)3NI and AgSCF3 realized, we re-examined various other previously reported ligands, which have enjoyed a measure of success in Pd-catalyzed cross-coupling reactions.[12] Our survey revealed that only dialkylbiarylphosphine based ligands were successful carrying out this transformation, while other ligands such as 5 or 6 did not perform well even with higher catalyst loadings. Accordingly, we were successful in converting electron-rich, -neutral and -deficient aryl bromides to their respective aryl trifluoromethyl sulfides in 2 hours at 80 °C using 1.5 - 3.5 mol % of Pd and 1.65 – 3.85 mol % of 1. Electron-neutral and electron-rich substrates were coupled more efficiently than their electron-poor analogs. This effect has previously been noted in the coupling of aryl halides with NaNO2.[11] Substrates containing acid-sensitive functional groups, such as BOC-protected anilines and nitriles, were tolerated and coupled in high yield along with substrates containing ketones, esters, and free NH groups of anilines (Table 3). Aryl bromides containing bulky ortho-groups, e.g., o-cyclohexyl and o-phenyl groups, could also be coupled successfully, although they required the use of the smaller ligand XPhos (3) (Table 3). Table 3 Pd-catalyzed coupling of aryl bromides.[a] Heteroaryl bromides such as those containing indoles, pyridines, quinolines, thiophenes and furans, were also viable substrates (Table 4). Unfortunately, attempts to extend this methodology to the coupling of aryl chlorides or aryl triflates were unsuccessful. We are currently working to understand and overcome these limitations. Table 4 Pd-catalyzed formation of heteroaryl–SCF3 compounds.[a] Finally, to demonstrate the utility of this method, we prepared an intermediate in the reported synthesis of Toltrazuril,[13] an antiprotozoal agent. Intermediate 14 can be assembled from readily available starting materials in an overall yield of 88%. The key C–SCF3 bond-forming process proceeded in 95% yield (Scheme 3). Scheme 3 Synthesis of Toltrazuril intermediate. In summary, we have developed a general method for the Pd-catalyzed Ar–SCF3 bond-forming reaction. Using this method, a wide range of aryl bromides were converted into their corresponding aryl trifluoromethyl sulfides. Additionally, we have been successful in generating a variety of heterocyclic aryl trifluoromethyl sulfides from heteroaryl bromide precursors. Due to the utility of Ar–SCF3 compounds as biologically active agents, and the mild reaction conditions employed, we expect this method to be immediately implemented in the discovery of novel compounds with pharmaceutical and agrochemical applications.

280 citations

Journal ArticleDOI
TL;DR: In this article, a review of polynuclear halide complexes of Bi(III) (polyhalidebismuthates, or PHBs) is presented, which consists of three parts.

196 citations