Document Type : Research Paper
Authors
Department of Chemistry, Kazerun Branch, Islamic Azad University
Abstract
Keywords
INTRODUCTION
Oxidation reactions are among the most important transformations in synthetic chemistry and offer important methodology for the introduction and modification of functional groups [1]. The selective oxidation of alcohols to aldehydes or ketones is a vital reaction in synthetic organic chemistry. In this way, chemists have used different kinds of metal salts and oxides in the form of homogeneous catalysts [2,3] or supported metal ions and supporting oxometal catalysts as heterogeneous systems [4,5].
Metallophthalocyanine (MPc) complexes have been used as alternative catalysts, because they have a similar structure to porphyrins and are cheaper and more stable to degradation [6]. The immobilization of MPc on solid supports is highly desirable to synthesize heterogeneous catalysts [7]. In these catalysts, Al2O3, TiO2, SiO2 and ZrO2 are commonly used as the supports. Bulk MPc in general cannot be used in industrial processes as they impart poor thermal stability that lead to fast deactivation of the catalyst. Furthermore, it is also known that bulk MPc leads to high combustion of organic molecules to carbon oxides [8]. There are some reports for the usage of cobalt and iron phthalocyanines as homogeneous catalysts for oxidation of alcohols [9,10]. Many different oxidants were used for the oxidation of alcohols such as pyridinium chlorochromate (PCC), pyridinium dichromate (PDC), KMnO4, MnO2, CrO3 and so on. Most of these oxidizing reagents which can be used in a research laboratory in stoichiometric amounts are expensive or toxic [11-17]. Thus, the advantages of environmentally friendly oxidizing agents, such as H2O2 and O2, have been extensively studied. H2O2 is attractive for producing active oxidation species in aqueous solution, with H2O as a by-product. However, to the best of our knowledge, there is no report for application of MPc supported on zinc oxide nanoparticles for oxidation of alcohols. In this work, the catalytic effect of Fe, Mn and CoPc supported on zinc oxide nanoparticles are investigated for oxidation of alcohols in the liquid phase.
MATERIALS AND METHODS
Methods for characterization
The FT-IR spectra were recorded using a Perkin Elmer FT-IR spectrometer by employing KBr pellet technique. X-ray powder diffraction (XRD) patterns of the samples were recorded using a Bruker Advance D8 Diffractometer with Cu Kα radiation (λ=0.154 nm). BET surface area was obtained from N2 adsorption isotherms at 77 K by a Strohlien. The SEM measurements were performed on a Holland Philips XL30 microscope. GC analysis of alcohols oxidation products was performed on a Shimadzu 8A, using authentic samples equipped with a TCD detector using OV-17, Propak-N, packed (2 m) columns and Helium as the carrier gas.
Preparation of catalysts
ZnO nanoparticles were prepared by the chemical precipitation method. Zinc nitrate hexahydrate {Zn(NO3)2.6H2O} and ammonium hydroxide solution {NH4.OH} were used as starting chemicals. 12 M solution of aqueous ammonium hydroxide was added drop by drop to the 0/35 M solution of zinc nitrate hexahydrate in room temperature until pH of the solution reaches 7 and precipitate Zn cations in the form of hydroxides. After the white precipitate was formed, it was filtered and washed by deionized water. Metal salt (9.6 × 10-5 mol), phthalonitrile (3.84 × 10-4 mol), urea (1.92 × 10-3 mol) and ammonium heptamolybdate (8 × 10-4 mol) were mixed and finely grounded and were added to the white precipitate. This white precipitate was stirred and homogenized and was placed in an oven under temperature of 100 °C for 24 h. The mixture was heated in air to 300 °C at a heating rate of 2 °C/min and then the mixture was calcined at 400 °C under vacuum for 4 h [18,19]. Formation of ZnO nanoparticles was confirmed with XRD and for MPc with UV-VIS and IR spectra.
CoPc/nano-ZnO: IR (KBr): ν, cm-1 1520, 1428, 1336, 1289, 1161, 1120, 1088/3424, 1635, 1385, 1113.
FePc/nano-ZnO: IR (KBr): ν, cm-1 1518, 1414, 1332, 1293, 1164, 1119, 1084/3423, 1635, 1384, 1115.
MnPc/nano-ZnO: IR (KBr): ν, cm-1 1509, 1418, 1335, 1287, 1166, 1115/3424, 1636, 1385, 1113.
Experimental procedure
In a typical reaction, a mixture of 0.5 g catalyst and 30 mmol of alcohol (cyclohexanol, n-hexanol or benzyl alcohol) were stirred under nitrogen in a 50 ml round bottom flask equipped with a condenser and a dropping funnel at room temperature for 30 min. Then 14 mmol of TBHP or H2O2 was added as oxidizing reagents. The resulting mixture was then refluxed for 8 h under N2 atmosphere. After filtration, the solid was washed with solvent and then the reaction mixture was analyzed by GC (Shimadzu 8A). Products identification was done with GC-MS (Finnigan TSQ-7000).
RESULTS AND DISCUSSION
Characterization of the catalysts
Formation of MPc was confirmed with UV-VIS spectra (Fig. 1) and shows the same spectra of unsupported MPc. These spectra confirm formation of different polymorphs of MPcs in the zinc oxide matrix [20].
Fig. 1. Diffuse reflectance spectrum of: (a) CoPc/nano-ZnO (b) FePc/nano-ZnO, and (c) MnPc/nano-ZnO.
The XRD pattern presented in Fig. 2 indicates that ZnO nanoparticles are formed. There is no significant change in the XRD pattern with 10 wt.% CoPc supported on ZnO nanoparticles which confirms that CoPc dispersed through pores does not change the ZnO structure.
Fig.2. XRD patterns of (a) ZnO nanoparticles, and (b) 10 wt.% CoPc/nano-ZnO.
Scanning electron micrograph (SEM) of a typical sample of 10 wt.% CoPc supported on ZnO nanoparticles is shown in Fig. 3. It is clarified that the sizes of the particles are in the ranges of 30-50 nm. This result was coincident with the particle sizes calculated from the Scherrer equation.
Specific surface area measured with BET method was 65 m2/g for ZnO nanoparticles and 52 m2/g for 10 wt.% CoPc/nano-ZnO. This reduction in specific surface area for the supported CoPc may be an indication of encapsulation of CoPc in the ZnO pores.
Fig. 3. SEM photographs of 10 wt.% CoPc/nano-ZnO.
Catalytic oxidation of cyclohexanol with TBHP
The use of TBHP as an oxidant was based on the earlier studies on the oxidation of hydrocarbon [6], this oxidant was found to cause minimal destruction of the phthalocyanine catalyst, and to give better selectivity of the products. The performance of the set of samples prepared as catalysts for the oxidation of alcohols was tested with TBHP. At first, the reactivity of a model compound, cyclohexanol, was examined under a variety of experimental condition (Table 1). In all reactions were produced only one product (cyclohexanone) therefore, selectivity (%) is 100 with respect to it. The research results showed that three kinds of metallophthalocyanines could catalyze cyclohexanol oxidation with TBHP. The activity of the catalysts was as follows: CoPc/nano-ZnO > FePc/nano-ZnO > MnPc/nano-ZnO. In the presence of 10% CoPc/nano-ZnO, conversion percentage of cyclohexanol was 83.4% with TBHP as an oxidant. Contrastive experiment results show that cyclohexanol oxidation with TBHP did not occur in the absence of the catalyst under the same reaction condition. In addition, unsupported ZnO has shown lower catalytic activity than the supported catalyst.
Table 1. Oxidation of cyclohexanol with TBHP in the presence of metallophthalocyanines supported on zinc oxide nanoparticles
Influences of reaction time on cyclohexanol oxidation reaction
In this experiment, the change in conversion (%) of cyclohexanol in the presence of TBHP oxidant and 10% CoPc/nano-ZnO catalyst was monitored and plotted with respect to time (Fig. 4). The reaction was carried out at reflux temperature for 8 h with 0.5 g catalyst and 30 mmol cyclohexanol and 14 mmol TBHP in a round bottom flask and some samples was drawn out at regular intervals and analyzed by GC. Fig. 4 shows that the conversion of cyclohexanol increases continuously until 83.2% as time increases and then remains constant after 7 h, therefore duration about 7-8 h is proper reaction time.
Fig. 4. The effect of reaction time on cyclohexanol conversion. Reaction condition: 0.5 g 10% CoPc/nano-ZnO catalyst, cyclohexanol 30 mmol, TBHP 14 mmol, reflux temperature
Influences of various metals on cyclohexanol oxidation reaction
We have studied the catalytic properties of iron, cobalt and manganese phthalocyanines and to investigate the effects of different metals on cyclohexanol oxidation reaction under the same reaction conditions. Table 1 has summarized the results and confirms the high catalytic activities of these MPcs. The research results indicated that all the three metallophthalocyanines could catalyze cyclohexanol oxidation with TBHP. The activity of the catalysts was as follows: CoPc/nano-ZnO > FePc/nano-ZnO > MnPc/nano-ZnO. Irfan Acar [21] has reported that Co phthalocyanine and in the liquid phase, a conversion percent of benzyl alcohol 42% was obtained. They also concluded that Co phthalocyanine acts better than Fe phthalocyanine.
Effect of substrates and oxidants on cyclohexanol oxidation reaction
In this study, experiments on various selected alcohols were performed and the comparisons with respect to conversion and product selectivity are represented in Table 2. Higher conversion was obtained for cyclohexanol on 10% CoPc/nano-ZnO catalyst using TBHP oxidant. Table 2 shows that the reactivity of the alcohols toward oxidation with TBHP and H2O2 on 10% CoPc/nano-ZnO catalyst depends on the particular structure of the substrate and type of oxidant. It shows that TBHP is more efficient oxidant due to weaker O-O bond with respect to H2O2 and the following order has been observed for the percentage of conversions of alcohols: 2°> benzylic > 1°.
In this regard, it is worth noting that using H2O2 as reactant the complexes lose their characteristic color during the course of the reaction. UV-VIS spectroscopy of the recovered catalysts evidenced the degradation of the MPc complexes. This behavior contrasts with that of TBHP which does not produce decomposition of the MPc complexes as assessed by UV-VIS and IR spectra at the end of the reaction. Similar UV-VIS and IR spectra were obtained for the catalyst before and after the reaction test with TBHP and the result confirms that the catalyst is stable, decomposition of MPc was negligible and its reactivity was preserved.
Table 2. Effect of the 10% CoPc/nano-ZnO catalyst in the oxidation of different alcohols.
Mechanism of catalytic oxidation
According to the literature [22], the electrocatalytic oxidation of cyclohexanol by metallophthalocyanine at first produces ROO. and RO. radicals as shown in Scheme 1. The RO. and ROO. radicals produced then react with cyclohexanol according to Fig. 5.
Fig. 5. Proposed mechanism for the production of cyclohexanone in cyclohexanol catalytic oxidation by metallophthalocyanine.
CONCLUSIONS
Metallophthalocyanines supported on zinc oxide nanoparticles were directly prepared with the addition of required materials for the formation of metallophthalocyanines to the white precipitate of Zn hydroxide and heated to 400 °C under vacuum. These metallophthalocyanines supported on zinc oxide nanoparticles prove to be reactive, effective and reusable catalysts for catalytic oxidation of different alcohols with excellent conversion percentage and 100% selectivity by using TBHP as oxidizing reagent.
ACKNOWLEDGMENTS
We gratefully acknowledge financial support from the Research Council of kazerun Branch, Islamic Azad University.
CONFLICT OF INTERESTS
The authors declare that there is no conflict of interests regarding the publication of this paper.