Yusuke Kumatabara scite author profile

An efficient synthesis of cyclic carbonates from epoxides and CO 2 under mild reaction conditions was achieved via the use of triethylamine hydroiodide as a simple yet effective bifunctional catalyst. The importance of the bifunctional feature of the catalyst was clearly demonstrated in the present work via control experiments and 1 H NMR studies. The scalability of this catalytic system was also demonstrated.

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Tetraalkylammonium Salts as Hydrogen‐Bonding Catalysts

Shirakawa

Liu

Kaneko

et al. 2015

Angew Chem Int Ed

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Although the hydrogen-bonding ability of the α-hydrogens on tetraalkylammonium salts is often discussed in the chemistry of phase-transfer catalysts, the catalysis that utilizes the hydrogenbond donor properties of tetraalkylammonium salts remains unknown. In the present work, we demonstrated hydrogen-bonding catalysis with newly designed tetraalkylammonium salt catalysts in Mannich-type reactions. Both the structure and the hydrogenbonding ability of the new ammonium salts were investigated via Xray diffraction analysis and NMR titration studies.Tetraalkylammonium salts are recognized as representative organocatalysts, [1] and are often used as phase-transfer catalysts for the activation of anionic nucleophiles through the formation of an ion pair with an ammonium cation. [2] Although the structures of tetraalkylammonium salts are commonly expressed as 1a shown in Figure 1, the actual ionic structures are discussed differently. [3][4][5] The positive charge of ammonium salts delocalized on the α-hydrogen atoms, which are known to interact with an anionic counterion through hydrogen bonding, as shown in 1A. Reetz proved the delocalization of the positive charge in tetraalkylammonium salts by X-ray crystal analysis of tetrabutylammonium salts such as tetrabutylammonium enolate and phenoxide. [3] Furthermore, DFT calculations support the delocalized structures of ammonium salts, which include chiral ammonium salts. [4,5] The interaction between α-hydrogens on the chiral tetraalkylammonium salt catalyst and the enolate oxygen was thought to be important in the transition-state model of asymmetric phase-transfer reactions. [5] However, despite the interesting hydrogen-bonding ability of the α-hydrogens on tetraalkylammonium salts, the catalysis that could utilize such properties is, to the best of our knowledge, still unknown. Herein, we report a new dimension of tetraalkylammonium salt as a hydrogen-bonding catalyst that utilizes the characteristic properties of the α-hydrogens on the catalyst. [6] Figure 1. Structures of tetraalkylammonium salt.To realize the efficient hydrogen-bonding catalysis of a tetraalkylammonium salt, we designed a new tetraalkylammonium salt, 2, which was readily prepared via the methylation of a commercially available 2,6-piperidinecarboxylate, 3 (Scheme 1). The ammonium salt 2 possesses carboxylate groups at the α-carbon, which enhance the hydrogen-bonding ability of the α-hydrogens. Furthermore, the six-membered structure of the piperidine backbone fixes the acidic α-hydrogens to a position that is appropriate for bidentate binding to an anionic group. [7] Scheme 1. Design and synthesis of a new tetraalkylammonium salt for use as a hydrogen-bonding catalyst.To obtain structural information of newly prepared tetraalkylammonium salts 2, we performed an X-ray diffraction COMMUNICATIONanalysis of ammonium iodide 2a (Figure 2). [8] The crystal structure of 2a provided important structural information. As expected, the hydrogen-bonding interactions between the α-hydrogens and the...

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A new generation of chiral phase-transfer catalysts

2016

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Phase-transfer catalysis has long been recognized as a versatile method for organic synthesis. In particular, during more than the past three decades, asymmetric phase-transfer catalysis based on the use of structurally well-defined chiral catalysts has become a topic of great scientific interest. Although various effective chiral catalysts have already been reported and these catalysts were utilized for practical asymmetric transformations, further design and development of new chiral phase-transfer catalysts are still attractive research subjects in organic chemistry due to the high utility and practicability of phase-transfer-catalyzed reactions. This review focuses on the recent examples of newly designed effective chiral phase-transfer catalysts.

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Chiral quaternary phosphonium salts as phase-transfer catalysts for environmentally benign asymmetric transformations

2016

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Hydrogen-bonding catalysis of sulfonium salts

et al. 2017

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Although quaternary ammonium and phosphonium salts are known as important catalysts in phase-transfer catalysis, the catalytic ability of tertiary sulfonium salts has not yet been well demonstrated. Herein, we demonstrate the catalytic ability of trialkylsulfonium salts as hydrogen-bonding catalysts on the basis of the characteristic properties of the acidic α hydrogen atoms on alkylsulfonium salts.The importance of onium salt compounds has been established in the field of organic chemistry. 1 Alkyl-ammonium, phosphonium, and sulfonium salts are some of the most important and reliable onium salt reagents in organic synthesis (Fig. 1). These compounds are often utilized as very useful reagents in the construction of organic building blocks, and the reactions using these reagents appear in textbooks of organic chemistry as important, named reactions. 2,3 Furthermore, quaternary ammonium and phosphonium salts are also known as reliable catalysts, which are used to promote a wide variety of organic transformations as phase-transfer and/or base catalysts. 4 Despite the wide synthetic utility of onium salt compounds as reagents and catalysts, the catalytic ability of tertiary sulfonium salts has not yet been demonstrated well in organic synthesis. 5 The limitation of sulfonium salt catalysts has been attributed mainly to the high reactivity and instability of the compounds with acidic α hydrogen atoms. To create new possibilities for sulfonium salts as catalysts, we focused on the hydrogen-bonding abilities of α hydrogen atoms on alkylsulfonium salts when we reported the use of type 1 tetraalkylammonium salts as hydrogen-bonding catalysts on the basis of the characteristic properties of the α hydrogen atoms (Fig. 2). 6,7 Herein, we demonstrate the catalytic ability of trialkylsulfonium salts in hydrogen-bonding catalysis. 8 Fig. 1 Onium salts in organic synthesis.Based on the design of type 1 tetraalkylammonium salts as effective hydrogen-bonding catalysts, 6 we focused on simple type 2 trialkylsulfonium salts (Fig. 2). The structures of the α hydrogen atoms that binded to the iodide anion compared favorably to the X-ray crystal structures of ammonium iodide 1a and sulfonium iodide 2a. 9,10 Furthermore, we expected the acidity of the α hydrogen atoms of 2a to approximate the acidity of 1a, based on the reported pKa values. 11 Fig. 2 Comparison between ammonium iodide 1a and sulfonium iodide 2a.

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