Superparamagnetic Fe(OH) - ACS Publications - American Chemical

May 6, 2015 - AGFM, MDK Co., Iran, www.mdk-magnetic.com). Trans- mission electron microscopy (TEM) were carried out at 120 kV. (Philips model CM120)...
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Superparamagnetic Fe(OH)3@Fe3O4 nanoparticles: An efficient and recoverable catalyst for tandem oxidative amidation of alcohols with amine hydrochloride salts Marzban Arefi, dariush saberi, Meghdad Karimi, and Akbar Heydari ACS Comb. Sci., Just Accepted Manuscript • DOI: 10.1021/co5001844 • Publication Date (Web): 06 May 2015 Downloaded from http://pubs.acs.org on May 12, 2015

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Superparamagnetic Fe(OH)3@Fe3O4 nanoparticles: An efficient and recoverable catalyst for tandem oxidative

amidation

of

alcohols

with

amine

hydrochloride salts Marzban Arefi, † Dariush Saberi, ‡ Meghdad Karimi, † and Akbar Heydari, †* †

Chemistry Department, Tarbiat Modares University, P.O. Box 14155-4838 Tehran, Iran, Fax:

(+98)-21- 82883455; phone: (+98)-21-82883444; Email: [email protected]

Fisheries and Aquaculture Department, College of Agriculture and Natural Resources, Persian

Gulf University, Bushehr 75169, Iran KEYWORDS Oxidative amidation, Tandem oxidation, Magnetic nanoparticles, Iron oxide, Heterogeneous catalyst ABSTRACT Magnetic Fe(OH)3@Fe3O4 nanoparticles were successfully prepared and characterized. This magnetic nanocomposite was employed as an efficient, reusable and environmentally benign heterogeneous catalyst for the direct amidation of alcohols with amine hydrochloride salts. Several derivatives of primary, secondary and tertiary amides were synthesized in moderate to good yields in the presence of this catalytic system. The catalyst was successfully recycled and reused up to six times without significant loss of its catalytic activity.

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INTRODUCTION Amide bond formation is one of the most important and often used reactions in the synthesis of natural products, polymers, pharmaceuticals, and fine chemicals.1 Owing to the importance of the amide functionality in biological systems and pharmaceutical chemistry (More than 25% of available drugs contain an amide unit.2) the development of an efficient and practical protocol for the amide bond formation remains a great challenge in organic chemistry. Traditionally, amides are synthesized by the reaction of an amine with a carboxylic acid (or their derivatives) or by using a coupling reagent.3 These methodologies are generally expensive and produce a significant amount of chemical waste.4 However these traditional methods suffer from poor atom-efficiency and/or the use of highly hazardous reagents. To circumvent these problems, another alternative amide formation protocols have been explored. These includes, the Staudinger reaction,5 the Schmidt reaction,6 the Beckmann rearrangement,7 dehydrogenative amidation of alcohols,8 hydroamidation of alkynes,9 amino carbonylation of haloarenes,10 direct amide synthesis from alcohols with amines or nitroarenes,8c,

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transamidation of primary

amides12 and oxidative amidation of aldehydes.13 Although significant achievements were made, most of the strategies mentioned above have not been applied in industry owing to drawbacks such as the use of expensive transition metals and harsh reaction conditions. Among the amide formation protocols, the tandem oxidative amidation of alcohols with amine salts has received sustained attention over the past few years. These methods require the use of transition metals, such as copper,14 zinc,15 ruthenium,8a, 11b, 16 rhodium17 and iridium18 or heterogeneous catalysts, such as Au/TiO2 system,19 Au/DNA nanohybrids,8b and alumina-supported silver clusters.20 Iron is abundant, inexpensive, safe, and environmentally benign. On the other hand, a variety of iron salts as well as complexes are commercially available. So to compete with these methods 2

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involving expensive metals, studies on iron-catalyzed formation of amides from aldehydes or alcohols have been paid more attention in this area. In this context, Gaspa et al. reported the base-free iron-catalyzed oxidative amidation of alcohols with N-chloroamines, generated from toxic and non atom-economic N-chlorosuccinimide.21 Recently, Ghosh et al. reported a tandem oxidative amidation of benzyl alcohols with amine salts using Fe(NO3)3-(2,2,6,6Tetramethylpiperidin-1-yl)oxyl as catalyst, molecular oxygen and tert-butyl hydroperoxide as the oxidants.22 Other iron salts such as FeCl223 and FeSO4.7H2O24 have also been used for synthesis of amides from aldehydes and amine hydrochloride salts. Although, these iron-catalytic systems, for the preparation of amides, promote the drawbacks existing with the other transition metal catalytic systems, the separation of the desired product and the catalyst from the reaction mixture can be challenging in these homogeneous catalytic methodologies. In recent years, magnetic nanoparticles-supported catalysts have been successfully deployed in a variety of important organic transformations.25 Because they are highly stable and they can be separated from the reaction mixture by using an external magnet for further using. In continuation of our efforts in using magnetic nanoparticles as a catalyst support in organic reactions26 herein we describe an inexpensive, magnetically reusable and environmentally friendly catalytic system (Fe(OH)3@Fe3O4) for the direct oxidative amidation of alcohols with amine hydrochloride salts.

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RESULTS AND DISCUSSION As can be seen in Scheme 1, our catalytic system was prepared through a simple pathway (for details see experimental section).

Scheme 1. Preparation of magnetic Fe(OH)3@Fe3O4 nanoparticles. The prepared catalyst was characterized using some instrumental techniques such as XRD, SEM, TEM, TGA and VSM. The XRD pattern of this catalyst is shown in Figure 1. In particular, seven characteristic peaks at 2θ equal 21.5°, 35.4°, 41.7°, 50.9°, 63.7°, 68.0° and 75.1°, which correspond to the Miller indices values {h k l} of {111}, {220}, {311}, {400}, {422}, {511} and {440} respectively. The XRD pattern resembles that of Fe3O4 nanoparticles and no signal is observed from the Fe(OH)3 phase, indicating that the Fe(OH)3 compound is amorphous. Nanoparticles morphology was evaluated by SEM (Figure 2) and TEM (Figure 3) images. Coreshell structure and spherical in shape with a smooth surface morphology of the particles are clearly seen in these images. On the other hand, these images confirm that the particle size is below 40 nm. TGA recorded under nitrogen atmosphere for Fe3O4 (Figure 4(A)) and Fe(OH)3@Fe3O4 MNPs (Figure 4(B)) determining this catalyst consisting 9.4 wt% of Fe(OH)3 and 90.6 wt% of Fe3O4 (see Supporting Information (SI)). The magnetic feature of the catalyst was confirmed by vibrating sample magnetometry (VSM). Magnetizing (emu/g) as a function of applied field (Oe) is depicted in Figure 5. The magnetization curve demonstrate that these Fe(OH)3@Fe3O4 nanoparticles (Possessed magnetic saturation (Ms) about 40.0 emu/g) have superparamagnetic properties which accounts for easy recovery of this catalyst.

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Figure 1: XRD pattern of Fe3O4 and Fe(OH)3@Fe3O4.

Figure 3: TEM image of the catalyst.

Figure 2: SEM image of the catalyst.

Figure 4: TGA results of Fe3O4 and Fe(OH)3@Fe3O4.

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Figure 5: Magnetization curve of Fe3O4 and the catalyst.

The catalytic activity of Fe(OH)3@Fe3O4 MNPs was tested in tandem oxidative amidation of alcohols with amine hydrochloride salts. Initially, the reaction of benzyl alcohol with benzylamine hydrochloride salt was tested as the model reaction under the following conditions: benzyl alcohol 1{1} (0.5 mmol, 1 equiv.), benzyl amine hydrochloride salt 2{5} (0.75 mmol, 1.5 equiv.), t-BuOOH (3.0 equiv.), CaCO3 (1.5 equiv.), CH3CN (1.0 mL), under Ar atmosphere at 25 o

C. Under these conditions, after six hours of reaction time, the corresponding product, N-

benzylbenzamide 3{1,5}, was formed in just 18% yield. To increase the yield of the product, various conditions were screened that the results are summarized in Table 1. Table 1. Optimization of the reaction conditions.a

Entry

Cat. (mg)

Oxidant

Base

Solvent

1 2 3 4 5 6

20 20 20 20 20 20

t-BuOOH t-BuOOH t-BuOOH t-BuOOH t-BuOOH t-BuOOH

CaCO3 CaCO3 CaCO3 CaCO3 CaCO3 CaCO3

CH3CN CH3CN CH3CN CH3CN DMF H2O

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Temp.(°C) Yield (%)b 25 60 80 100 80 80

18 40 87 51 10 35

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7 20 t-BuOOH CaCO3 DMSO 80 8 20 m-CPBAc CaCO3 CH3CN 80 d 9 20 UHP CaCO3 CH3CN 80 10 20 H2O2 CaCO3 CH3CN 80 11 20 ----CaCO3 CH3CN 80 12 20 t-BuOOH Cs2CO3 CH3CN 80 13 20 t-BuOOH K2CO3 CH3CN 80 14 20 t-BuOOH Na2CO3 CH3CN 80 15 --t-BuOOH CaCO3 CH3CN 80 16 30 t-BuOOH CaCO3 CH3CN 80 17 15 t-BuOOH CaCO3 CH3CN 80 18 20e t-BuOOH CaCO3 CH3CN 80 a Reaction conditions: benzyl alcohol 1{1} (0.5 mmol, 1 equiv.), benzyl amine hydrochloride salt 2{5}(0.75 mmol, 1.5 equiv.), oxidant (3 equiv.), base (1.5 equiv.), solvent (1 mL), under Ar atmosphere, 6 h. bYield of the isolated product is based on the alcohol. cmeta-Chloroperoxybenzoic acid. dUrea hydrogen peroxide. e20 mg of Fe3O4 nanoparticles were used.

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