Effect of thermal parameters and pH on obtaining copper ferrite via EDTA-Citrate complexation method

Silva, Larissa Nogueira e; Silva, Maitê Medeiros de Santana e; Santos, Francisco Klebson Gomes dos; Souza, Carlson Pereira de; Moriyama, André Luis Lopes; Santos, Andarair Gomes dos

doi:10.1590/S1517-707620210004.1371

ABSTRACT

The synthesis of ceramic materials such as ferrite has been widely studied in recent years, due to their properties that make these materials have excellent applications in technology, as well as in photocatalytic processes and as catalysts. To obtain the copper ferrite phase the EDTA-Citrate complexation method was used, varying pH (5, 7 and 9), temperature (600, 800 and 1000 °C) and calcination time (2, 7 and 12 h). Composition, morphology and structural analyzes were performed by X-ray fluorescence spectroscopy, X-ray dispersive energy, scanning electron microscopy and X-ray diffraction, respectively. Crystalline phase of copper ferrite (CuFe₂O₄) with tetragonal structure and secondary phase of Fe₂O₃ and CuO was verified by XRD analysis. Regarding the chemical composition analyzes, percentage deviations of the samples and the theoretical value for copper and iron were calculated. It was obtained minimum values of 0.16 - 0.08% (atomic%, EDS) and 16 - 8% (atomic%, XRF) in relation to copper and iron, respectively, for the sample obtained under pH 9, calcined at 600 °C for 12 h. The variation of the synthesis condition via EDTA-Citrate directly influenced the morphology of copper ferrite, presenting agglomerated particles, pore formation, irregular spheres, and even powder sintering.

Keywords
thermal parameters; pH; copper ferrite; EDTA-Citrate; crystallinity and morphology

1. INTRODUCTION

Spinel-type ferrite is a ceramic material that has been widely studied in recent years, for its magnetic properties, chemical and thermal stability, allowing these materials to have a variety of applications in technological areas such as energy integrated circuits, millimeter waves and magnets permanent [¹1 SHETTY, K., RENUKA, L., NAGASWARUPA, H.P., et al., “Comparative study on CuFe2O4, ZnFe2O4 and NiFe2O4: Morphology, Impedance and Photocatalytic studies”, Materials Today, pp. 11806-11815, 2017.] in addition to being used in photocatalytic processes [²2 SHARMA, R., SINGHAL, S., “Photodegradation of textile dye using magnetically recyclable heterogeneous spinel ferrites”, Journal of Chemical Technology & Biotechnology, v. 90, pp. 955-962, 2015. ], microwave radiation isolators [³3 KUANR, B.K., VEERAKUMAR, V., MARSON, R., et al. “Nonreciprocal microwave devices based on magnetic nanowires”, v. 94, pp. 202-505, 2009.], magnetic fluids [⁴4 SUJATHA, C., REDDY, K.V., BABU, K.S., et al. “Effects of heat treatment conditions on the structural and magnetic properties of MgCuZn nano ferrite”, Ceramics international, v. 38, pp. 5815-5820, 2012.], as well as catalysts [⁵5 BALDISSERA, M.R., SILVA, M.R.A., SILVEIRA C.A., et al. “Síntese e caracterização de ferritas de Zn e Mn provenientes de pilhas inutilizadas”, Cerâmica, v. 60, pp. 52-56, 2014.]. Ferrite has crystalline structures and diverse compositions, with chemical formula MFe₂O₄, where M represents bivalent metallic cations, such as copper, cobalt, nickel, zinc, among others [⁶6 LEAL, E., DANTAS, J., OLIVEIRA, P.L., et al. “Avaliação da formação do híbrido NiFe2O4@SiO2 e sua performance na immobilization of GOx”, Revista matéria, v. 23, 2018.]. There are different techniques from which these materials can be synthesized, including sol-gel [²2 SHARMA, R., SINGHAL, S., “Photodegradation of textile dye using magnetically recyclable heterogeneous spinel ferrites”, Journal of Chemical Technology & Biotechnology, v. 90, pp. 955-962, 2015. ], co-precipitation [⁷7 NIKOLIĆ, V.N., VASIĆ, M., MILIĆ, M.M., “Observation of low- and high-temperature CuFe2O4 phase at 1100 °C: The influence of Fe3+ ions on CuFe2O4 structural transformation”, v. 44, pp. 21145-21152, 2018.], solvothermal [⁸8 YANG, X., ZHANG S., YU, O., et al. “Solvothermal synthesis of porous CuFe2O4 nanospheres for high performance acetone sensor”, Sensors and Actuators B: Chemical, v. 270, pp. 538-544, 2018.], combustion [¹1 SHETTY, K., RENUKA, L., NAGASWARUPA, H.P., et al., “Comparative study on CuFe2O4, ZnFe2O4 and NiFe2O4: Morphology, Impedance and Photocatalytic studies”, Materials Today, pp. 11806-11815, 2017.], hydrothermal synthesis and EDTA-Citrate complexation [⁹9 DE MEDEIROS, I.A.F., MORIYAMA, A.L.L., SOUZA, C.P., “Effect of synthesis parameters on the size of cobalt ferrite crystallite”, Ceramics International, v. 43, pp. 3962-3969, 2017.]. This latter method has been widely used for the production of ceramic powders due to its numerous advantages, such as easy control of stoichiometry, high purity and crystallinity of the products, since the choice of a chemical process is very important to obtain good quality ferrite [¹⁰10 SANTOS, A.G., COSTA, I.K.F., SANTOS, F.K.G., et al. “Efeito do método de complexação combinando EDTA - citrato e coprecipitação em meio oxalato na síntese da SrCo0,8Fe0,2O3-δ, “HOLOS”, v. 3, pp. 30-43, 2015., ¹¹11 SILVA, M.M.S., SENA, M.S., LOPES-MORIYAMA, A.L., et al. “Experimental planning of the synthesis of strontium molybdate by EDTA-citrate and its structural influence, morphology and optical bandgap”, Ceramics International, v. 44, pp. 16606-16614, 2018.].

Copper ferrite (CuFe₂O₄) may have a tetragonal or cubic structure, the first being more stable at low temperatures and the second at high temperatures [¹²12 PHABHU, D., NARAYANASAMY, A., SHINODA, K., et al. “Grain size effect on the phase tranformation temperature of nanostructred CuFe2O4”, Journal of Appied physics, v. 112, pp. 39-44, 1994.]. Due to its low toxicity, thermal and chemical stability, this material can be used as a gas sensor, presenting high sensorial potential. YANG et al. [⁸8 YANG, X., ZHANG S., YU, O., et al. “Solvothermal synthesis of porous CuFe2O4 nanospheres for high performance acetone sensor”, Sensors and Actuators B: Chemical, v. 270, pp. 538-544, 2018.] produced copper ferrite by the solvothermal method for gas sensor application, presenting excellent performance. They obtained a high and fast sensory response that exhibited a value of 20.1 to 250 °C, compared with the commercial gas detector responses that the maximum was 3.6 at that same temperature, besides presenting a characteristic of the nanospheres of copper ferrite. Studies show that this ferrite also has a recovery capacity when used as a catalyst, showing a loss of only 8% of the reaction yield after five subsequent cycles [¹³13 CASAGRANDE, D.S., COSTA, W.V., HECHENLEITNER, A.A.W., et al. “Síntese e caracterização de nanopartículas de ferritas do tipo ZnxCu1-xFe2O4 e a sua aplicação como catalisador em acetilação em óleos vegetais”, In: Congresso brasileiro de engenharia e ciência dos materiais, pp. 1964-1975, Natal, 2016.]. It can be used as a catalyst in organic reactions, such as phenol synthesis [¹⁴14 YANG, D., AN, B., WEI, W., et al. “A novel sustainable strategy for the synthesis of phenols by magnetic CuFe2O4-catalyzed oxidative hydroxylation of arylboronic acids under mild conditions in water”, Tetrahedron, v. 70, pp. 3630–3634, 2014.], Friedel-crafts acylation reactions [¹⁵15 PARELLA, R., NAVEEN, KUMAR, A., et al. “Catalytic Friedel–Crafts acylation: magnetic nanopowder CuFe2O4 as an efficient and magnetically separable catalyst”, Tetrahedron Letters, v. 54, pp. 1738-1742, 2013.] and alkoxylation of organic compounds [¹⁶16 YANG, S., XIE, W., ZHOU, H., et al. “Alkoxylation reactions of aryl halides catalyzed by magnetic copper ferrite”, Elsevier, v. 69, pp. 3415-3418, 2013.]. SHETTY et al. [¹1 SHETTY, K., RENUKA, L., NAGASWARUPA, H.P., et al., “Comparative study on CuFe2O4, ZnFe2O4 and NiFe2O4: Morphology, Impedance and Photocatalytic studies”, Materials Today, pp. 11806-11815, 2017.] conducted a comparative study on copper, zinc and nickel ferrite, which were synthesized by the simple combustion method, and morphological studies and photocatalytic studies were performed. The three ceramic materials presented efficiency as photocatalyst, but copper ferrite among the other synthesized materials presented higher photocatalytic potential in the decomposition of dyes with values of 94.5%, 82.8% and 65.3% for CuFe₂O₄, NiFe₂O₄ and ZnFe₂O₄, respectively.

The objective of this work is to obtain the copper ferrite synthesized by the EDTA-Citrate complexation method and to evaluate the influence of thermal parameters and pH on its chemical composition, structure and morphology.

2. MATERIALS AND METHODS

2.1 Synthesis of copper ferrite by EDTA-Citrate complexation method

The chemical reagents used in the synthesis of copper ferrite by the EDTA-Citrate complexation method were iron nitrate (Fe(NO₃)₃.9H₂O, Sigma-Aldrich), copper nitrate (Cu(NO₃)₂.3H₂O, Sigma-Aldrich), acid EDTA (C₁₀H₁₆N₂O₈, Synth). The three reagents were 99% pure, citric acid (C₂H₄O₂, Synth) 99.5% pure and ammonium hydroxide (NH₄OH, Impex) 28% pure in NH₃OH.

The EDTA-Citrate complexation method based on the methodology described by SANTOS et al. [¹⁰10 SANTOS, A.G., COSTA, I.K.F., SANTOS, F.K.G., et al. “Efeito do método de complexação combinando EDTA - citrato e coprecipitação em meio oxalato na síntese da SrCo0,8Fe0,2O3-δ, “HOLOS”, v. 3, pp. 30-43, 2015.], SILVA et al. [¹¹11 SILVA, M.M.S., SENA, M.S., LOPES-MORIYAMA, A.L., et al. “Experimental planning of the synthesis of strontium molybdate by EDTA-citrate and its structural influence, morphology and optical bandgap”, Ceramics International, v. 44, pp. 16606-16614, 2018.] and SILVA et al. [¹⁷17 SILVA, A.R., QUIXADÁ, G.F., SANTOS, P.E.C., et al. “Avaliação da perovsquita BaCeO3 como catalisador na conversão de óleo de soja em biodiesel via rota etílica”, In: Andrade, D. E. (org), Petróleo e Outros Combustíveis, 1 ed., capítulo 9, Belo Horizonte, Poisson, 2019.] is shown in Figure 1 and briefly described below: initially, some amount of acidic EDTA was diluted in ammonium hydroxide at a ratio of 1 g:10 mL and kept under controlled stirring and heating (solution 1), then to solution 2 (Fe(NO₃)₃.9H₂O) and then solution 3 (Cu(NO₃)₂.3H₂O) was added to solution 1 and then solution 4. Subsequently citric acid was added (solution 4) and then the temperature was increased and controlled by about 80 °C until gel formation. The pH of solution 4 is corrected by the addition of NH₃OH or with nitric acid solution (10 mol/L) when necessary. The molar ratio of acid EDTA, citric acid and metal ions to obtain ceramic powder was 1:1.5:1. Table 1 presents the experimental synthesis conditions. The pre calcination condition for all samples, regardless of pH, was the same: 230 °C, for 180 min with a heating rate of 5 °C/min.

Figure 1
Proposed methodological route for CuFe₂O₄ synthesis based on the EDTA-Citrate complexation method.

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Table 1
Experimental synthesis conditions for obtaining CuFe₂O₄ ceramic powders based on the EDTA-Citrate complexation method.

2.2 Structural and morphological characterizations

The samples were characterized by X-ray Diffraction (XRD) in order to identify the crystalline phases. The measurements were obtained with an X-ray diffractometer (Shimadzu DRX-7000), using Cu-Kα radiation, with 40 kV voltage and 30 mA current. The diffractograms were obtained in the 2θ range ranging from 10 to 80 degrees in 5 °C/min steps. To identify the crystalline phase (s), the X´Pert High Score version 4.8 software was used.

The morphology of the samples was evaluated by field emission scanning electron microscopy (SEM) (MEV-FEG) (Carl Zeiss, Auriga model) coupled with dispersive energy spectrometer (EDS), which was used for Chemical composition analysis, which was also obtained by X-ray Fluorescence Spectroscopy, using an EDX-7000 Shimadzu detector spectrometer. The enlargements were performed on a scale of 1 micrometer (1 µm) and / or 200 nanometers (200 nm).

3. RESULTS

3.1 X-ray diffraction (XRD) of EDTA-Citrate copper ferrite

Figure 2 shows the diffractograms of CuFe₂O₄ samples synthesized via EDTA-Citrate complexation method, as shown in Table 1.

Figure 2
Copper Ferrite Diffractograms (A) pH 5, (B) pH 7 e (C) pH 9.

Figure 2 (A) shows the diffractograms of the samples synthesized in an acid medium (pH 5) with different temperature conditions and calcination time according to Table 1. Analyzing the samples obtained at 600 °C with different isotherm times, it was found that the sample is composed of iron oxide (Fe₂O₃). And, the increase in the calcination time favors the formation of the desired phase. In general, the temperature of 600 °C is not sufficient to obtain pure copper ferrite by EDTA-Citrate complexation method independent of the isotherm time since the material is partially amorphous together with a mixture of oxides for the synthesis condition in pH 5. However, maintaining pH 5 and thermally treating at 1000 °C for 2 h and 12 h, in both isotherms more well-defined peaks can be observed, and the presence of single-phase CuFe₂O₄ can be identified, according to the crystallographic plans presented in the diffractogram.

Samples synthesized at pH 7 with calcination conditions of 800 °C for 7 h are shown in Figure 2 (B). This experimental condition synthesized in triplicate presents better defined peaks, characteristic of crystalline solids, indexed as a spinel of copper ferrite. Finally, the diffractograms for samples synthesized with pH 9 are shown in Figure 2 (C). In a basic reaction medium and at 600 °C, a noticeable difference is noticed in the formation of the desired phase depending on the calcination time, where the heat-treated sample for 2 h presents a mixture of oxides while the increase in the treatment time for 12 h results in a more crystalline material that presents only copper oxide as impurity. However, when calcined at 1000 °C and basic medium, they are monophasic and crystalline regardless of the calcination time.

The XRD standards used to identify the samples obtained (Figure 2) are the tetragonal copper ferrite spinel (I41 / amd (141), ICSD N°: 016666), rhombohedral iron oxide (R-3c (167), ICSD N°: 022505 and monoclinic copper oxide (C2 / c (15), ICSD N°: 067850). There were no additional peaks related to the secondary phase in the diffraction patterns in samples pH 5 (1000 °C - 2 and 12 h) pH 7 (800 °C - 7 h) and pH 9 (1000 °C - 2 and 12 h), ensuring phase purity within the limit of XRD detection.

The results presented for the materials obtained in different experimental conditions showed that regardless of the pH of the synthesis it was not possible to obtain the desired pure phase when the organometallic complex was calcined at a temperature of 600 °C even when the isotherm time was increased by 2 for 12 h of time, however, when the calcination temperature was 1000 °C, the formation of copper ferrite free of impurities is verified, which leads us to believe that the temperature variable has greater influence within the process of formation of the desired material when synthesized by the EDTA-Citrate complexation method. With the increase mainly in temperature and followed by the reaction time, there is an increase in the internal energy and entropy of the system. To minimize the disorder caused, the crystals coalesce with each other due to the greater energy provided by the system, resulting in a crystalline material with a stable phase [⁹9 DE MEDEIROS, I.A.F., MORIYAMA, A.L.L., SOUZA, C.P., “Effect of synthesis parameters on the size of cobalt ferrite crystallite”, Ceramics International, v. 43, pp. 3962-3969, 2017.].

Although pH is a very important variable in complexation reactions, it is observed that in this case, it did not cause a significant change in the structure or phase formation for temperatures of 800 - 1000 °C for the studied calcination times. When analyzing the heat treatment condition at 600 °C at pH 5 and 9, the desired non-formation is observed, with the exception of the sample obtained in basic medium at 600 °C with 12 h of isotherm where the formation of ferrite is observed copper and a small amount of copper oxide.

NIKOLIĆ et al. [⁷7 NIKOLIĆ, V.N., VASIĆ, M., MILIĆ, M.M., “Observation of low- and high-temperature CuFe2O4 phase at 1100 °C: The influence of Fe3+ ions on CuFe2O4 structural transformation”, v. 44, pp. 21145-21152, 2018.] synthesized copper ferrites by the coprecipitation method in the same temperature range (300 °C to 1100 °C) and observed the presence of iron oxide (Fe₂O₃) in all calcination temperatures, in addition to the formation of the copper oxide (CuO) at a temperature of 500 °C. SHETTY et al. [¹1 SHETTY, K., RENUKA, L., NAGASWARUPA, H.P., et al., “Comparative study on CuFe2O4, ZnFe2O4 and NiFe2O4: Morphology, Impedance and Photocatalytic studies”, Materials Today, pp. 11806-11815, 2017.] also synthesized copper ferrites using the simple combustion method at 500 °C, verified the presence of two secondary phases, Fe₂O₃ and CuO. From there, it can be seen that the method and the synthesis conditions are fundamental to obtain crystalline powders with an impurity-free phase. The methodology used for the production of copper ferrites calcined at 800 - 1000 °C, regardless of the pH of the synthesis, proved to be quite efficient with regard to obtaining single-phase powders since the literature shows that CuFe₂O₄ has already been produced by different methods in this same temperature range to no avail.

3.2 Chemical Composition Analysis by X-ray Fluorescence Spectroscopy (XRF)

By X-ray Fluorescence Spectroscopy analysis, the chemical composition of the synthesized samples was studied. Table 2 presents the atomic percentage values (at. %) of copper and iron for the samples analyzed, in addition to the deviation from the theoretical value.

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Table 2
Chemical composition of CuFe₂O₄ analyzed by XRF.

The theoretical atomic percentage of copper and iron are 33.33 and 66.67%, respectively, analyzing only these two atoms in the molecule. There are relatively high deviations between the atomic percentages obtained by XRF and the theoretical value, with minimum values 16 and 8% and maximum values 33 and 17% for copper and iron, respectively. The sample obtained under pH 9 conditions, calcined at 600 °C for 12 h, showed the smallest deviation among all synthesized samples. Deviations between the theoretical and experimental percentage may be related to the formation of secondary phases [¹⁸18 OH, W.D., DONG, Z., HU, Z.T., et al. “A novel quasi-cubic CuFe2O4–Fe2O3 catalyst prepared at low temperature for enhanced oxidation of bisphenol A via peroxymonosulfate activation”, Journal of Materials Chemistry A, v. 44, pp. 22208-22217, 2015.] identified in diffractograms and also to losses during material processing. Another point to be made is that the reagents used are hygroscopic in nature and during the weighing process, despite careful handling of the reagents, they absorb water quickly and this error may be embedded in the theoretical stoichiometric calculation to obtain of copper ferrite.

3.3 Morphological analysis by scanning electron microscopy (SEM)

The following Figures present the results of scanning electron microscopy (SEM) analysis of CuFe₂O₄ samples obtained via EDTA-Citrate complexation method under different conditions as shown in Table 1. Figure 3 (A) and Figure 3 (B) show magnification of 10000x and 20000x, respectively. The morphology of the sample with synthesis conditions: pH 5, calcined at 600 °C for 2 h and those of the pH 5 sample (magnified on the same scale) calcined at 600 °C for 12 h (Figure 4), are non-uniform and present pores. These results are similar to those of SHETTY et al. [¹1 SHETTY, K., RENUKA, L., NAGASWARUPA, H.P., et al., “Comparative study on CuFe2O4, ZnFe2O4 and NiFe2O4: Morphology, Impedance and Photocatalytic studies”, Materials Today, pp. 11806-11815, 2017.] that calcined the samples at 500 °C and obtained by microscopic analysis, structures with pores.

Figure 3
Scanning electron microscopy of CuFe₂O₄ sample obtained at pH 5 (600 °C / 2 h) conditions. (A) 1 μm and (B) 200 nm.

Figure 4
Scanning electron microscopy of CuFe₂O₄ sample obtained at pH 5 (600 °C / 12 h) conditions. (A) 1 μm and (B) 200 nm.

Figure 5 represents a pH 5 sample calcined at 1000 °C for 2 h. Being (A) and (B) with magnifications of 10000x and 20000x, respectively. When calcined at 1000 °C, the sample exhibits characteristics of a sintering process.

Figure 5
Scanning electron microscopy of CuFe₂O₄ sample obtained at pH 5 (1000 °C / 2 h) conditions. (A) 1 μm and (B) 200 nm.

Figures 6, 7 and 8 represent CuFe₂O₄ samples at pH 7 conditions, calcined at 800 °C for 7 h. Figures (A) have magnification of 10000x and figures (B) of 20000x. It is observed in the other irregular and agglomerated spherical particles, with similar shapes to those obtained by MANIKANDAN et al. [¹⁹19 MANIKANDAN, V., VANITHA, A., KUMAR, E.R., et al. “Effect of in substitution on structural, dielectric and magnetic properties of CuFe2O4 nanoparticles”, Journal of Magnetism and Magnetic Materials, v. 423, pp. 477-483, 2017.].

Figure 6
Scanning electron microscopy of CuFe₂O₄ sample obtained at pH 7 sample (1) conditions (800 °C / 7 h). (A) 1 μm and (B) 200 nm.

Figure 7
Scanning electron microscopy of CuFe₂O₄ sample obtained at pH 7 sample (2) conditions (800 °C / 7 h). (A) 1 μm and (B) 200 nm.

Figure 8
Scanning electron microscopy of CuFe₂O₄ sample obtained at pH 7 sample (3) conditions (800 °C / 7 h). (A) 1 μm and (B) 200 nm.

Figure 9, where (A) has magnification of 10000x and (B) of 20000x, obtained with conditions of pH 9 at 600 °C for 12 h, particle agglomerates, as well as the presence of small pores. While Figures 10 are samples of pH 9, the calcination conditions being: (A) 600 °C for 2 h, (B) 1000 °C for 2 h and (C) 1000 °C for 12 h. In these samples, particles with different shapes and non-uniform sizes are observed.

Figure 9
Scanning electron microscopy of CuFe₂O₄sample obtained at pH 9 (600 °C / 12 h) conditions. (A) 1 μm and (B) 200 nm.

Figure 10
Scanning electron microscopy of CuFe₂O₄sample obtained at pH 9 conditions - 1 μm (A) 600 °C / 2 h, (B) 1000 °C / 2 h and (C) 1000 °C / 12 h.

The different synthesis conditions influenced the morphology of the samples, presenting non-uniform shapes and sizes with inhomogeneous particle agglomerations.

Table 3 presents the atomic percentage values of copper and iron for the samples analyzed by X-ray dispersive energy (EDS), in addition to the deviation from the theoretical value.

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Table 3
Chemical composition of CuFe₂O₄ analyzed by EDS.

The deviations between the atomic percentages of the synthesized samples and the theoretical value were calculated, obtaining minimum values 0.16 and 0.08% and maximum values 20.95 and 10.48% for copper and iron, respectively. Such minimum deviation values were found in the sample obtained under pH 9 conditions, calcined at 600 °C for 12 h. The values obtained in the analysis can be considered reliable within the margin of error and the equipment itself, in the case of a semi-quantitative analysis.

4. CONCLUSIONS

Single-phase CuFe₂O₄ was obtained via EDTA-Citrate complexation method regardless of the pH of the medium (pH 5, 7 or 9), however the heat treatment adopted directly influences the purity of the phase. Among the experimental conditions studied, pure copper ferrite was obtained when synthesized in an acidic and basic medium at 1000 °C for 2 h and neutral pH at 800 °C for 7 h. The different synthesis conditions directly influenced the morphology of copper ferrite obtained by EDTA-Citrate method. Variations in particle agglomeration, pore formation and irregular sphere shapes were observed, as well as sintering the powder.

ACKNOWLEDGMENT

Laboratory Pós-Colheita/UFERSA, CITED/UFERSA, CSAMA/UERN, LMNRC/UFRN and CNPq.

BIBLIOGRAPHY

¹
SHETTY, K., RENUKA, L., NAGASWARUPA, H.P., et al., “Comparative study on CuFe₂O₄, ZnFe₂O₄ and NiFe₂O₄: Morphology, Impedance and Photocatalytic studies”, Materials Today, pp. 11806-11815, 2017.
²
SHARMA, R., SINGHAL, S., “Photodegradation of textile dye using magnetically recyclable heterogeneous spinel ferrites”, Journal of Chemical Technology & Biotechnology, v. 90, pp. 955-962, 2015.
³
KUANR, B.K., VEERAKUMAR, V., MARSON, R., et al “Nonreciprocal microwave devices based on magnetic nanowires”, v. 94, pp. 202-505, 2009.
⁴
SUJATHA, C., REDDY, K.V., BABU, K.S., et al “Effects of heat treatment conditions on the structural and magnetic properties of MgCuZn nano ferrite”, Ceramics international, v. 38, pp. 5815-5820, 2012.
⁵
BALDISSERA, M.R., SILVA, M.R.A., SILVEIRA C.A., et al “Síntese e caracterização de ferritas de Zn e Mn provenientes de pilhas inutilizadas”, Cerâmica, v. 60, pp. 52-56, 2014.
⁶
LEAL, E., DANTAS, J., OLIVEIRA, P.L., et al “Avaliação da formação do híbrido NiFe₂O₄@SiO₂ e sua performance na immobilization of GOx”, Revista matéria, v. 23, 2018.
⁷
NIKOLIĆ, V.N., VASIĆ, M., MILIĆ, M.M., “Observation of low- and high-temperature CuFe₂O₄ phase at 1100 °C: The influence of Fe³⁺ ions on CuFe₂O₄ structural transformation”, v. 44, pp. 21145-21152, 2018.
⁸
YANG, X., ZHANG S., YU, O., et al “Solvothermal synthesis of porous CuFe₂O₄ nanospheres for high performance acetone sensor”, Sensors and Actuators B: Chemical, v. 270, pp. 538-544, 2018.
⁹
DE MEDEIROS, I.A.F., MORIYAMA, A.L.L., SOUZA, C.P., “Effect of synthesis parameters on the size of cobalt ferrite crystallite”, Ceramics International, v. 43, pp. 3962-3969, 2017.
¹⁰
SANTOS, A.G., COSTA, I.K.F., SANTOS, F.K.G., et al “Efeito do método de complexação combinando EDTA - citrato e coprecipitação em meio oxalato na síntese da SrCo₀,₈Fe_0,2O_3-δ, “HOLOS”, v. 3, pp. 30-43, 2015.
¹¹
SILVA, M.M.S., SENA, M.S., LOPES-MORIYAMA, A.L., et al “Experimental planning of the synthesis of strontium molybdate by EDTA-citrate and its structural influence, morphology and optical bandgap”, Ceramics International, v. 44, pp. 16606-16614, 2018.
¹²
PHABHU, D., NARAYANASAMY, A., SHINODA, K., et al “Grain size effect on the phase tranformation temperature of nanostructred CuFe₂O₄”, Journal of Appied physics, v. 112, pp. 39-44, 1994.
¹³
CASAGRANDE, D.S., COSTA, W.V., HECHENLEITNER, A.A.W., et al “Síntese e caracterização de nanopartículas de ferritas do tipo Zn_xCu_1-xFe₂O₄ e a sua aplicação como catalisador em acetilação em óleos vegetais”, In: Congresso brasileiro de engenharia e ciência dos materiais, pp. 1964-1975, Natal, 2016.
¹⁴
YANG, D., AN, B., WEI, W., et al “A novel sustainable strategy for the synthesis of phenols by magnetic CuFe₂O₄-catalyzed oxidative hydroxylation of arylboronic acids under mild conditions in water”, Tetrahedron, v. 70, pp. 3630–3634, 2014.
¹⁵
PARELLA, R., NAVEEN, KUMAR, A., et al “Catalytic Friedel–Crafts acylation: magnetic nanopowder CuFe₂O₄ as an efficient and magnetically separable catalyst”, Tetrahedron Letters, v. 54, pp. 1738-1742, 2013.
¹⁶
YANG, S., XIE, W., ZHOU, H., et al “Alkoxylation reactions of aryl halides catalyzed by magnetic copper ferrite”, Elsevier, v. 69, pp. 3415-3418, 2013.
¹⁷
SILVA, A.R., QUIXADÁ, G.F., SANTOS, P.E.C., et al “Avaliação da perovsquita BaCeO₃ como catalisador na conversão de óleo de soja em biodiesel via rota etílica”, In: Andrade, D. E. (org), Petróleo e Outros Combustíveis, 1 ed., capítulo 9, Belo Horizonte, Poisson, 2019.
¹⁸
OH, W.D., DONG, Z., HU, Z.T., et al “A novel quasi-cubic CuFe₂O₄–Fe₂O₃ catalyst prepared at low temperature for enhanced oxidation of bisphenol A via peroxymonosulfate activation”, Journal of Materials Chemistry A, v. 44, pp. 22208-22217, 2015.
¹⁹
MANIKANDAN, V., VANITHA, A., KUMAR, E.R., et al “Effect of in substitution on structural, dielectric and magnetic properties of CuFe₂O₄ nanoparticles”, Journal of Magnetism and Magnetic Materials, v. 423, pp. 477-483, 2017.

Publication Dates

Publication in this collection
05 Jan 2022
Date of issue
2021

History

Received
11 Mar 2020
Accepted
31 May 2021

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Samples	% Cu	Error (%)	% Fe	Error (%)
pH 5 (600 °C / 12h)	39.86	19.59	60.14	9.80
pH 5 (1000 °C / 2h)	42.53	27.59	57.47	13.80
1- pH 7 (800 °C / 7h)	44.39	33.16	55.62	16.58
2- pH 7 (800 °C / 7h)	43.51	30.52	56.49	15.26
3- pH 7 (800 °C / 7h)	44.46	33.39	55.54	16.69
pH 9 (600 °C / 12h)	38.66	15.99	61.34	7.99
pH 9 (1000 °C / 2h)	44.08	32.24	55.92	16.12

Samples		% Cu	Error (%)	% Fe	Error (%)
Multiphase	pH 5 (600 °C / 2h)	33.17	0.49	66.83	0.25
Multiphase	pH 5 (600 °C / 12h)	34.93	4.79	65.07	2.39
Single phase	pH 5 (1000 °C / 2h)	30.71	7.87	69.29	3.94
Multiphase	pH 5 (1000 °C / 12h)	29.79	10.63	70.21	5.32
Single phase	1- pH 7 (800 °C / 7h)	33.91	0.37	66.09	0.87
Single phase	2- pH 7 (800 °C / 7h)	33.18	0.46	66.82	0.25
Single phase	3- pH 7 (800 °C / 7h)	34.12	2.36	65.88	1.18
Multiphase	pH 9 (600 °C / 2h)	31.52	5.44	68.48	2.63
Multiphase	pH 9 (600 °C / 12h)	33.28	0.16	66.72	0.08
Single phase	pH 9 (1000 °C / 2h)	32.22	3.34	67.78	1.67
Multiphase	pH 9 (1000 °C / 12h)	26.35	20.95	73.65	10.48

Brasil

Brasil

Effect of thermal parameters and pH on obtaining copper ferrite via EDTA-Citrate complexation method

ABSTRACT

1. INTRODUCTION

2. MATERIALS AND METHODS

2.1 Synthesis of copper ferrite by EDTA-Citrate complexation method

2.2 Structural and morphological characterizations

3. RESULTS

3.1 X-ray diffraction (XRD) of EDTA-Citrate copper ferrite

3.2 Chemical Composition Analysis by X-ray Fluorescence Spectroscopy (XRF)

3.3 Morphological analysis by scanning electron microscopy (SEM)

4. CONCLUSIONS

ACKNOWLEDGMENT

BIBLIOGRAPHY

Publication Dates

History

Synthesis	Experimental conditions of synthesis
Synthesis	pH	Calcination (°C)	Rate (°C.min^-1)	Isotherm (h)
1	5	600	5	2
2	9	600	5	2
3	5	1000	5	12
4	9	1000	5	12
5	5	600	5	12
6	9	600	5	12
7	5	1000	5	2
8	9	1000	5	2
9	7	800	5	7
10	7	800	5	7
11	7	800	5	7