Hydrothermal synthesis, structural and catalytic studies of CuBi2O4 nanoparticles

Abstract

     In the present work CuBi2O4 nano-spinel has been synthesized via mild hydrothermal method at 180°C for 10 h. The synthesized nanomaterials were characterized by several techniques to emphasis the structure and properties of produced materials. The crystal structure was investigated by X-ray powder diffraction method and the values of the refined unit cell volume and the structure properties were studied by using the Rietveld analysis is done using Fullprof program. The results shew the formation of tetrahedral structure with space group P4/ncc for this sample. Also, the morphologies of the synthesized materials were figured out by field emission scanning electron microscope (FE-SEM). According to the FESEM images, several nano cubic form of particles grew on micro spherical particles. As well, the catalytic performance of obtained CuBi2O4 was studied in Biginelli reaction. The reaction conditions of this study optimized by experimental design method. This experiment stablished high catalytic performance of copper bismuth oxide in compare with some other metal oxide catalysts. Also, the results shew this product is reusable homogenous catalyst.

Keywords: CuBi2O4, Hydrothermal Method, catalytic activity, Structural study

1. Introduction

     Catalytic technology has important role on economy growth; Therefore, the method of producing, beginning materials of catalyst and the yield of process are undeniable, so that these factors are considered in this research. Synthesizing 3,4 dihydropyrimidin-2-(1H)-ones (DHPMs) as its usage in biology and pharmacology is one of the most important reactions in organic chemistry [1, 2], such as antiviral, anti-inflammatory, antibacterial and antitumor [3, 4]. This three-component reaction, scheme 1, is known as Biginelli reaction [5]. One negative point of view to this reaction is the low yield of the products [6], therefore, many publications try to offer various catalysts for improving the efficiency of the reaction, among them metal oxides are known as heterogeneous catalyst like: ZnO/MTSA.SiO2 [7], TiO2-MWCNT [8], MnO2-MWCNT [9], Al2O3, CuO [10], RuO2 [11], Fe3O4-MWCNT[12], Bi2Mn2O7 [13] and so forth. Copper bismuth oxide is p-type spinel metal oxide which has been synthesized by several methods like: solid state [14], metal organic decomposition[15, 16], electrochemical method [17], sol-gel method [18], sono-chemical approach [19], microwave method [20], thermal deposition [20], hydrothermal synthesis [21], and complexation [22]. The mild hydrothermal method which is used in this work creates spherical morphology for CuBi2O4 nanoparticles. Some features of CuBi2O4 lead to using this oxide in different fields. For example, high oxidation protentional causes to use this metal oxide as cathodes in lithium batteries [23]. Also, its narrow band gap energy causes to use as sensitizer semiconductors [15, 24]. Also, The low photon energy leads to using as strong response to visible light [24]. Some other characteristics such as photocatalytic activity [25], dielectric properties [26], magnetic features [27] have been investigated recently. There is no previous research to stablish heterogeneous catalytic activity of CuBi2O4 so far. Therefore, we try to present structural and catalytic properties of this sample in this investigation by using reasonable data. Preparing pure phase of Cubi2O4 was denotated by X-ray powder diffraction method and the structure properties were studied by using X’Pert package and Fullprof program. Also, FT-IR and TGA analysis confirmed synthesizing this spinel structure and FE-SEM determined its morphology. 

2. Experimental details

2.1 Materials and methods

     All chemicals were of analytical grade, obtained from commercial sources (Merck company), and used without further purification. Phase identifications were performed on a powder X-ray diffractometer D5000 (Siemens AG, Munich, Germany) using CuKα radiation in the range 2θ = 10-90° and the XRD data was analyzed by using X’Pert package and Fullprof program. The morphology of the obtained materials was examined with a field emission scanning electron microscope (Hitachi FE-SEM model S-4160). FT-IR spectra were recorded on a Tensor 27 (Bruker Corporation, Germany). The thermogravimetric analysis (TGA) has been recorded by STA PT 1600 thermal analysis performed between 25-800°C with the 5°C/min constant rate of heating under air atmosphere in alumina pan. The purity of products was checked by thin layer chromatography (TLC) on glass plates coated with silica gel 60 F254 using n-hexane/ethyl acetate mixture as mobile phase.

2.2 Synthesis of CuBi2O4

     In this method, at first 1 mmol Cu(NO3)2 was dissolved in 25ml of distilled water and stirred for 15min. Then 2 mmol Bi(NO3)2 was added to the solution and stirred for 15min again. After that, the solution of 25 ml of NaOH (2 M) was added dropwise to receive pH = 14. At the end, the solution was transferred to the 100 ml Teflon-lined stainless-steel autoclave for hydrothermal treatment at 180°C for 10 h. When the reaction was completed, it was cooled to room temperature. The obtained CuBi2O4 was washed with deionized water three times to remove impurity and achieve nurture pH. The prepared powder was washed with distilled water and dried at 110 °C for 20 min under normal atmospheric conditions.

2.3 Preparation DHPMs

     For synthesizing 3,4 dihydropyrimidin-2-(1H)-ones, a mixture of benzaldehyde (1 mmol), ethyl acetoacetate (1 mmol), urea (1.2 mmol) and different amounts of CuBi2O4 as catalyst were heated and magnetically stirred in a round-bottom flask under solvent free conditions [28]. The reaction progress was checked by thin layer chromatography (TLC) [6:4 hexane/ ethyl acetate as eluent]. At the end, the solid product was washed with deionized water to separate the unreacted urea for dissolving in water. Then, the precipitation was gathered and dissolved in ethanol to separate the solid catalyst.

3. Results and discussions

3.1 PXRD analysis

     The XRD diffraction pattern of synthesized copper bismuth oxide is shown in Fig. 1. The investigation of XRD data has been done by X’Pert High Score package and Fullprof program [29]. Identification of structure type has been studied by using X’pert package confirms the formation of single phase CuBi2O4. The results indicate that all the diffraction peaks of CuBi2O4 can be quite well indexed in tetragonal structure (space group P4/ncc) and the best fit with the least difference is carried out (Fig. 2). Complete adaptability and perfect performance in Rietveld refinement require best amount of initial values and type of space group, which are taken from X’Pert package. The refined lattice parameters are: a = b = 8.525 and c = 5.822.

         The crystallite size of particles can be calculated by Scherrer’s equation:

                                                                                  (1)

     In this equation, D show particle size, λ is X-ray wavelength (0.154 nm) and β is broadening at half the maximum intensity of the peak. The largest peak is located at 28.008°. The obtained average crystallite size of synthesized CuBi2O4 nanoparticle is 32nm.

3.2. Morphological analysis

     For studying the morphology and the sizes of synthesized material FE-SEM was used. Figure 2 shows various magnificent of copper bismuth oxide. This figure shows micro spherical particles that nano cubic forms grow on their surface and create morphology like flower. The size of cuboid which is located on each sphere is between 30-50 nm.

3.3 Thermogravimetric analysis (TGA) analysis

     Thermogravimetric analysis (TGA) is a technique which determines characteristics of material by gaining weight as a result of increasing temperature. Figure 3 a and b show the TGA and DTA curves of as-prepared CuBi2O4. The sharp fall at the plot at the beginning up to 100 °C belong to losing moisture. After that the sample heated up to 800°C the curve continues with the normal slope which includes no weight loss that emphasizes on nonexistence of organic material and forming pure crystalline tetragonal phase.

3.4 Fourier transform infrared spectroscopy (FTIR) analysis

     FTIR spectra of as-prepared CuBi2O4 was observed in Fig. 4. There are two sharp peaks at 3166 cm-1 and 3440 cm-1 that is attributed to O-H bond stretching. Also, a peak which is located at 1641 cm-1 refers to bond bending of H2O. The peak at 1398 cm-1 assigns to stretching vibration of Bi-O bonds [30]. There is a peak at 497 cm-1 that is due to stretching vibration of Cu-O bonds [31].

3.2. Catalytic studies

3.2.1. Central Composite design and optimal condition in Biginelli reactions

     Central composite design (CCD) is broached by Box and Wilson that is one of the most popular methods in response surface methodology (RSM), especially for fitting a second order (quadratic) model [32, 33]. Each factor of this method consists of five levels (-a, -1, 0, 1, a). A CCD is composed of N, the number of experiments, that follow equation:

N = 2k + 2k + C0                                (Eq. 2)

     Where k is the number of factors. 2k is factorial points, 2k refers to star points and C0 is the number of central points, respectively [34]. In this research, three effective factors for Biginelli reaction that are the amount of the catalyst (A), temperature (B) and time of the reaction (C) were designed based on CCD as presented in table 1. As it can be seen, this design consists of 5 levels and twenty experiments including six central points and they were performed randomly in three days. Designed condition and the result are reported in table 2.

     A collection of mathematical and statistical methods is known as RSM method, which fits N experiments response of the CCD according to the quadratic equation 3:

                (Eq. 3)

     In this equation, βs are coefficients which in the first order sentences show main effects and in second order sentences refer to quadratic effects. Also, in the multiplication factors, statements are interaction effects. Y is the response at each experiment, here it is the demonstrated yield of the reaction; xis are the independent factors. In RSM, by conducting a regression analysis, the coefficients are calculated. In turn, analysis of variance (ANOVA) [35, 36], is used to differ the adequacy of the model.

     Analysis of the CCD data which is reported in table 2, by RSM based on equation 3, described the connection between the factors and the yield of the reaction, Y, as shown by equation 4, in which A, B and C are and the same as the coded factors introduced in table 2. 

Y =73.06 + 2.01A + 2.96B + 25.71C -1.25AB +1AC + 1.5BC -3.12A2 -9.84B2- 11.25C2   (Eq. 4)

     The ANOVA of the result model has been presented in table 3. P-value is smaller than 0.1, emphasizing on its significance at high confidence level (90%). As it could be seen from table 3, model had the p-value less than 0.0005, a fact which proves that the model is significant and emphasizes on the significance of the applied quadratic model. The p-value of lack of fit was much more than 0.05, i.e. 0.561, which also confirmed the importance of model. Moreover, the coefficients of determination (the R-square, adjusted–R-square) shows the quality of the fit. In this case, R2 equaled with 0.9493 that express a high degree of accordance of the response and the independent factors. High value of adjusted regression coefficient (R2-adj = 0.8923) which emphasizes on being as applied model.

To identify the model effect, the three–dimensional (3D) response surfaces plots of the response, based on equation (4), when one factor value was fixed at centre level and two other factors were changed are illustrated in Figures 5a and 5b. The curvature of the plot showed that there was interaction between the factors. It meant that the factors influenced the response interactively and not independently. The purpose of the optimization of factors was to find optimal conditions and define the best condition with the best yield. These conditions were achieved by maximizing the equation (3) when the amount of the catalyst was 0.016 g, at 130 ºC reaction temperatures, and 57.5 minuet reaction times. In this condition, the yield of experiment is 96%.

3.2.2. Recycling and leaching of the catalyst

Reusability of the catalysts is one of the most important factor to make it as an useful economical catalyst. So, checking the recyclability is a significant test. In this section, the reusability efficiency of this product was examined after two times separation and clear that the efficiency doesn’t have eye-catching changes. The separation of 3,4-dihydropyrimidin-2(1H)-one from CuBi2O4 was done by washing with ethanol -three times- and once with chloroform, then centrifuged (EBA 20 Hettich) with 3500 rpm and filtered for separating catalyst.  The catalytic reaction was repeated under similar conditions. The yield of the product approximately didn’t change a lot -91% and 90% after two times - that is established its recyclability without lacking obvious activity.  

For obtaining the leaching ability of the catalyst, the reaction has been stopped at half of the reaction time (30min). then the catalyst was separated from the reaction and the progress was continued under same condition. it was explored that no obvious progress was observed on the reaction efficiency (monitored by TLC). This result shows that the continues of the reaction has the direct relationship with existence of catalyst (figure 6).  

3.2.3. Comparison catalytic activity