Friedel‐Crafts reactions of indoles and chalconesa.
Abstract
Ionic liquids (ILs) immobilized on supports are among the most important derivatives of ILs. The immobilization process of ILs can transfer their desired properties to substrates. The combination of the advantages of ILs with those of support materials will derive new performances while retaining the properties of both moieties. As green media in organic catalytic reactions, based on utilizing the ability of ILs to stabilize the catalysts, they have many advantages over free ILs, including avoiding the leaching of ILs, reducing their amount, and improving the recoverability and reusability of both themselves and catalysts. This has critical significance from both environmental and economical points of view. Recently, ionic liquids immobilized on magnetic nanoparticles (MNPs) have drawn increasing attention in catalytic reactions and separation technologies and achieved substantial progress. The combination of MNPs and ILs gives magnetic‐supported ionic liquids, which exhibit the unique properties of ILs as well as facile separation by an external magnetic field. The excellent efficiency of this kind of immobilized ionic liquids offers a great advantage compared with other sorts of magnetic supports. In this chapter, the green catalytic processes and recent advances in organic synthesis catalyzed by ionic liquids immobilized on magnetic nanoparticles are highlighted.
Keywords
- ionic liquids
- magnetic nanoparticles
- green synthesis
- retrievable catalysts
1. Introduction
Ionic liquids (ILs) are progressively being studied for targeted chemical tasks due to their unique chemical and physical properties such as nonvolatility, nonflammability, thermal stability and controlled miscibility [1]. In spite of the fact that ILs contained several advantages, but their extensive practical application was still prevented by some drawbacks like high viscosity, difficult recyclability and high cost of ILs in large‐scale utilization [2]. Therefore, in order to decrease these difficulties, immobilized IL had been prepared as a new heterogeneous catalyst with the useful features of ILs and inorganic acids for catalyzed reactions [3]. Among several usages of ILs in organic chemistry, imidazolium ionic liquid‐type catalysts indicate one of the most successful developments [4]. This chapter focuses on the recent progress in organic synthesis catalayzed by inoic liquids immobilized on magnetic nanoparticles.
2. Ionic liquids immobilized on MNPs in multicomponent reactions
Recent studies represent that magnetic nanoparticles (MNPs) are excellent supports for ILs owing to their good stability, easily preparation and functionalization, high surface area, low toxicity and simple separation by external magnetic attractions [5]. These special features have made MNPs a convenient alternative to catalyst supports. As an example, a magnetically Fe3O4@SiO2 nanoparticle‐immobilized ionic liquid (MNPs@SiO2‐IL) was prepared by Azgomi and Mokhtary [6]. The MNPs@SiO2‐IL was assessed as a recyclable catalyst for the one‐pot synthesis of 1,3‐thiazolidin‐4‐ones with good to great efficiency under solvent‐less conditions. The catalyst could be simply recycled using a magnetic field and reused for 10 times with no considerable loss in its activity (Scheme 1).
A dicationic ionic liquid immobilized on superparamagnetic iron oxide nanoparticles (SPION‐ACl2) has been used as a green and powerful catalyst to effectively synthesis derivatives of
The synthesis of a magnetic nanoparticle‐supported polyoxometalate has been reported, and this nanoparticle has been used as an efficient heterogeneous catalyst to prepare
In another research, a magnetic‐supported acidic ionic liquid has been prepared and evaluated in one‐pot synthesis of spirooxindoles [9]. Main properties of this approach are simplicity, low price, high efficiency, wide application scope, reusability and easy retrieval of the catalyst by an external magnet (Scheme 4).
A chemoselective hydrogenation of
Anchoring AlxCly‐IL onto the silica‐coated
The synthesis of Fe3O4@SiO2/salen/Mn/IL/HPW has been performed through attaching H3PW12O40 on magnetite nanoparticles modified with ionic liquid [12]. The catalyst was used for one‐pot synthesis of thiazoloquinolines, in good to great efficiency under solvent‐less conditions (Scheme 7). The catalyst could be simply recovered using a magnetic field and reused ten times with no significant loss in its activity.
Sobhani and Pakdin‐Parizi have improved an efficient heterogeneous catalyst for the Mizoroki–Heck cross‐coupling [13]. In this technique,
The synthesis of hydroxyapatite‐encapsulated magnetic nanoparticles immobilized with diethyl aliphatic amine basic ionic liquids (HAP‐
Magnetic nanoparticles supported with polyoxometalates (POMs) via ionic interaction were acquired through an easy sonication between modified magnetic nanoparticles and polyoxometalates. This material can be used as a highly active acid catalyst and as a catalyst support for chiral amines [15]. The immobilization of POM on MNPs was obtained by sonication of a mixture of MNPs (MNP‐1 or MNP‐2) and POM (H3PW12O40) in dry THF (Scheme 10).
The Friedel‐Crafts reaction of indole and chalcone was selected to examine the acidic catalytic activity and reusability of the prepared MNP‐1‐PW and MNP‐2‐PW catalysts. As observed in Table 1, the reactions between diverse chalcones and indoles continued efficiently to result the desired products with a high efficiency. Both magnetic POMs showed excellent activity and reusability for 12 recycles.
Entry R1 R2 | MNP‐1‐PW | MNP‐2‐PW | ||||
---|---|---|---|---|---|---|
t/h Yieldb (%) | t/h Yieldb (%) | |||||
1 | H | 5‐MeO | 20 | 93 | 20 | 94 |
2 | H | 5‐Me | 20 | 96 | 20 | 96 |
3 | H | 5‐Br | 7 | 98 | 6 | 97 |
4 | H | 5‐Cl | 7 | 97 | 6 | 97 |
5 | H | 5‐I | 7 | 99 | 6 | 98 |
6 | H | 6‐Cl | 7 | 98 | 6 | 98 |
7 | 4‐Cl | H | 12 | 90 | 12 | 92 |
8 | 4‐Me | H | 12 | 88 | 12 | 90 |
Also, chiral amine hybrids with magnetic POMs were easily prepared by mixing MNP‐PW and chiral amine via sonication in dry THF (Scheme 11).
The MNP‐PW‐immobilized chiral amine catalysts were next applied in typical enamine‐based asymmetric direct aldol condensations. Acetone reacted with different aromatic aldehydes in the presence of 5 mol% of MNP‐1‐PW‐A, to give the desired products with high efficiency and enantioselectivities (Table 2).
Entry | R | t/h | Yieldb (%) | ee (%)c |
---|---|---|---|---|
1 | 2‐NO2C6H4 | 12 | 83 | 89 |
2 | 3‐NO2C6H4 | 12 | 87 | 89 |
3 | 4‐CF3C6H4 | 30 | 81 | 90 |
4 | 2‐CNC6H4 | 30 | 80 | 87 |
5 | 2‐ClC6H4 | 48 | 72 | 87 |
6 | 2‐BrC6H4 | 48 | 77 | 88 |
Also, aldol donors such as cyclohexanone and cyclopentanone worked very well in this catalytic system (Table 3). Moreover, the outcomes achieved from the similar reactions with POM‐chiral amine hybrid PW‐A given in Table 3 (entries 1 vs. 2). The magnetic POM‐immobilized catalyst MNP‐1‐PW‐A showed slightly higher stereoselectivity and enantioselectivity albeit with a little loss of activity. The resulted noncovalently immobilized catalyst could be reused up to 11 times with essentially no loss of activity and enantioselectivity.
Entry | N | R | t/h | Yieldb (%) | Syn/antic | eed (%) |
---|---|---|---|---|---|---|
1 | 1 | 4‐NO2C6H4 | 5 | 97 | 6:94 | 97 |
2e | 1 | 4‐NO2C6H4 | 6 | 86 | 23:77 | 95 |
3 | 1 | 2‐NO2C6H4 | 5 | 97 | 24:76 | 98 |
4 | 1 | 3‐NO2C6H4 | 5 | 96 | 16:84 | 98 |
5 | 1 | 4‐CF3C6H4 | 12 | 88 | 17:73 | 97 |
6 | 1 | 4‐ClC6H4 | 48 | 86 | 20:80 | 96 |
7 | 2 | 2‐NO2C6H4 | 8 | 98 | 13:87 | 99 |
8 | 2 | 3‐NO2C6H4 | 8 | 97 | 14:86 | 98 |
9 | 2 | 4‐NO2C6H4 | 6 | 97 | 14:86 | 97 |
10 | 2 | 4‐CF3C6H4 | 11 | 93 | 13:87 | 98 |
11 | 2 | 4‐ClC6H4 | 48 | 92 | 17:83 | 98 |
A suitable approach has been improved for preparation of retrievable Pd catalyst using immobilization of palladium nanoparticles on magnetic nanoparticles modified with functional ionic liquid [16]. The amine functionalized ionic liquid immobilized Pd nanoparticles in the Pd/IL‐NH2/SiO2/Fe3O4 catalyst demonstrates great catalytic activity for a wide diversity of aryl iodides and bromides in the Suzuki coupling reactions at ambient temperature (Scheme 12). Furthermore, the catalyst is able to be good distributed in the reaction media, simply retrieved from the reaction mixture by using a magnet, and reused for several times with no significant loss in activity. Because of all these advantages, this procedure is a green and appropriate for other important reactions catalyzed with metal.
Moreover, there is a report on synthesis of magnetic nanoparticles immobilized with Ni2+ ion‐containing 1‐methyl‐3‐(3‐trimethoxysilylpropyl) imidazolium chloride ionic liquid as a recoverable nanocatalyst for the Heck reaction at 100°C, and it can be applied after washing with no loss in activity (Scheme 14) [18].
γ‐Fe2O3 nanoparticles immobilized with 2‐Hydroxyethylammonium sulphonate (γ‐Fe2O3‐2‐HEAS) were prepared through the reaction of n‐butylsulfonated γ‐Fe2O3 with ethanolamine [19]. Here, the catalyst effectively increases the condensation of both aliphatic and aromatic aldehydes and thiols with malononitrile resulting in 2‐amino‐3,5‐dicarbonitrile‐6‐thio‐pyridines in good to excellent efficiency under solvent‐less conditions (Scheme 15). Separating the product and recycling the catalyst are easily performed using a suitable external magnet. The catalyst can be reused for five times with no significant loss in its catalytic activity.
An effective synthesis of 2,4,5‐trisubstituted imidazoles is achieved by silica‐coated magnetite nanoparticles immobilized with multi‐SO3H functionalized acidic ionic liquid (Scheme 16). Because of high performance, recoverability, short reaction times, efficiency of products and operational simplicity, this process is an attractive substitute for the green synthesis of 2,4,5‐trisubstituted imidazoles as biological and pharmaceutical‐related substances [20].
An ionic liquid stabilized iron‐containing mesoporous silica nanoparticles (Fe‐MCM‐41‐IL) was synthesized by fixing a triazolium ionic liquid on Fe‐coated MCM. The pyrimidine derivatives were synthesized through one‐pot method in the presence of Fe‐MCM‐41‐IL as an effective heterogeneous acidic IL catalyst from aldehydes, 2‐thiobarbituric acid and ammonium acetate under moderate condition in excellent efficiencies (Scheme 17). This procedure is greener compared with other reported methods because of its moderate conditions of reaction, excellent efficiencies and simple recycling of the catalyst [21].
A simple and effective process has been reported for synthesizing 3‐((3‐(trisilyloxy)propyl) propionamide)‐1‐methylimidazolium chloride ionic liquid supported on magnetic nanoparticles (TPPA‐IL‐Fe3O4) [22]. The TPPA‐IL‐Fe3O4 assessed as a recoverable heterogeneous catalyst for the alcohols acetylation with acetic anhydride under moderate conditions at ambient temperature with high efficiencies (Scheme 18).
The hydroxyl groups were chemoselectively acetylated in the existence of other reactive groups by using the synthesized catalyst. The acetylation of 4‐bormobenzyl alcohol did occur selectively in the presence of 4‐bromophenol, and the hydroxyl group of phenol was intact during this reaction (Scheme 19).
An ecologically friendly technique has been improved for preparing isobenzofuran‐1(3
The Fe3O4@MCM‐41‐SO3H@[HMIm][HSO4] efficiently catalyzed the one‐pot three‐component condensation of
The silica‐coated magnetic particles immobilized with 1‐methyl‐3‐(triethoxysilylpropyl) imidazolium chloride provided the corresponding supported ionic liquid. Substituting the Cl¯ anion through treatment with H2SO4 resulted in Bronsted ionic liquid 1‐methyl‐3‐(triethoxysilylpropyl) imidazolium hydrogensulfate (MNP‐[pmim]HSO4) [25]. The activity of the immobilized ionic liquid was studied as a catalyst for synthesizing the polysubstituted pyridines using condensation of aromatic aldehydes with acetophenones and ammonium acetate in modest to excellent efficiency under solvent‐less conditions (Scheme 22). The recycling of the catalyst can be simply performed using an external magnet, and it can be reapplied for at least seven times with no change in its activity.
Silica‐coated Fe3O4 magnetic nanoparticles immobilized with urea‐based ionic liquid [Fe3O4@SiO2@(CH2)3‐Urea‐SO3H/HCl] have been prepared [26]. The catalyst was studied for the synthesis of bis(indolyl)methane derivatives through the reaction between 2‐methylindole and aldehydes at ambient temperature under solvent‐free conditions. In addition, pyrano[2,3‐d]pyrimidinones were synthesized in the presence of the catalyst through the one‐pot condensation reaction of 1,3‐dimethylbarbituric acid, aldehydes and malononitrile under solvent‐less conditions at 60°C (Scheme 23).
3. Polymeric ionic liquids immobilized on magnetic nanoparticles
The successful synthesis of magnetic CoFe2O4 nanoparticles coated with basic poly(ionic liquids) was carried out, and the catalyst synthesized using the surface grafting technique (g‐p[VRIm][OH]/MCFs) (Scheme 24) had a better stability, greater loading of ionic liquids and good paramagnetism compared with that synthesized through the conventional copolymerization technique (co‐p[VRIm][OH]/MCFs) (Scheme 25) [27].
The activities of the catalysts were studied for the Knoevenagel condensation reaction of benzaldehyde with ethyl cyanoacetate and for the transesterification of glycerol trioleate (TG) with methanol (Scheme 26). The results showed that in contrast to the sample synthesized by the copolymerization technique, the catalysts had a good catalytic efficiency.
Because of the influence of steric hindrance and active sites, g‐p[VDoIm][OH]/MCFs showed a higher catalytic activity than co‐p[VDoIm][OH]/MCFs. The conversion of benzaldehyde was around 97% for g‐p[VDoIm][OH]/MCFs higher than 72.5% for co‐p[VDoIm][OH]/MCFs that was in accordance with the reaction of transesterification. Moreover,
4. Summary and outlook
According to this chapter, there are some interesting new advancements in ionic liquids supported on magnetic nanoparticles. There is a clear procedure including silica coating of magnetic nanoparticle core followed by functionalization using proper alkoxysilane derivatives. Easy modification of the magnetic iron oxide surfaces with organic ligands increases the adsorption of catalytically active metal nanoparticles, as highlighted with palladium‐mediated C‐C coupling and Pt‐catalyzed hydrogenation reactions. The high dispersity of the MNPs in different solvents is another advantage, when it exposes the surface‐bound active reaction sites for the reactants in an optimized way. This lets diffusion restriction to be dominated, which is generally found in microporous or mesoporous heterogenized solids. Clearly, the unique magnetic properties of the superparamagnetic particles lead to recyclable magnetic nanoparticles immobilized with ionic liquids for several times using a suitable magnet with no significant loss in their catalytic activity. The sustainable synthesis of magnetically retrievable ionic liquids using readily available reactants will also make this field of research green. Additional interesting improvement is the poly(ionic liquids) stabilized magnetic nanoparticles as a new group of heterogeneous catalyst that is mainly attractive in organic synthesis practiced in an ecologically friendly way. In the end, future efforts for more efficient protocols will still focus on the stability, sustainability, environmental impact and considerable cost and energy savings due to the growing needs of industry. These attempts will permit a wide diversity of industrial usages for ionic liquids immobilized on magnetic nanoparticles in the future.
Acknowledgments
Financial support by Rasht Branch, Islamic Azad University Grant No. 4.5830 is gratefully acknowledged.
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