Magnetic and Electrical Properties of MnxCu1-xFe2O4 Ferrite

Oliveira, Valesca Donizeti de; Rubinger, Rero Marques; Silva, Manoel Ribeiro da; Oliveira, Adhimar Flávio; Rodrigues, Geovani; Ribeiro, Vander Alkmin dos Santos

doi:10.1590/1980-5373-MR-2015-0511

Abstract

In the present work, mixed manganese-copper ferrite of composition Mn_xCu_1-xFe₂O₄ (within x=0.40, 0.42, 0.44, 0.46, 0.48 and 0.50) have been investigated for their electric and magnetic properties such as dc resistivity, Curie temperature, saturation magnetization. Mn_xCu_1-xFe₂O₄ ferrite samples were prepared by uniaxial pressing from the oxide mixture, synthesized at 1000°C during 45 hours and finally heated to 1200°C by 5h, at room atmosphere. The X-ray diffractograms show that the samples with different compositions were formed by compact structure spinel with cubic cell. The saturated magnetization of the Mn_xCu_1-xFe₂O₄ ferrites increased with x up to 0.46, which presented the smallest coercitive field. All samples showed hysteresis characteristic of soft magnetic materials. This electrical behavior is compatible with an insulator. The results were analyzed in the framework of grain/barrier model.

Keywords
Ferrites; Spinel Structure; Magnetic Properties; Mn-Cu ferrites

1. Introduction

Mixed manganese/copper ferrites having high Curie temperatures and magnetization depending on the composition form an important class of magnetic materials used in many technological application¹1 Chen D, Liu HY, Li L. One-step synthesis of manganese ferrite nanoparticles by ultrasonic wave-assisted ball milling technology. Materials Chemistry and Physics. 2012;134(2-3):921-924..

The magnetic particles with smaller size become single domain in contrast with the usual multi domain structure for bulk magnetic material exhibiting superparamagnetization. Magnetic particles exhibiting superparamagnetic behavior display higher saturation magnetization and low coercivity having potential applications e.g., as magnetic resonance imaging contrast agents, in ferrofluids based technology, information storage device, gas sensors²2 Kumar ER, Jayaprakash R, Devi GS, Reddy PSP. Synthesis of Mn substituted CuFe2O4 nanoparticles for liquefied petroleum gas sensor applications. Sensors and Actuators B: Chemical. 2014;191:186-191.. For instance, a recent application of mixed ferrite Mn-Cu is a methane gas sensor for the oil industry³3 Kumar ER, Jayaprakash R, Devi GS, Reddy PSP. Magnetic, dielectric and sensing properties of manganese substituted copper ferrite nanoparticles. Journal of Magnetism and Magnetic Materials. 2014;355:87-92.. The magnetic properties and gassensing efficiency of the material depends on its microstructural properties, which are related to its method of preparation.

The synthesis of spinel manganese ferrite has been investigated extensively in recent years due to their structural, thermal, physical, chemical and particularly due to their magnetic properties⁴4 Rosales MI, Plata AM, Nicho ME, Brito A, Ponce MA, Castaño VM. Effect of sintering conditions on microstructure and magnetic properties of Mn-Zn ferrites. Journal of Materials Science. 1995;30(17):4446-4450.^,⁵5 Sharma US, Sharma RN, Shah R. Physical and Magnetic Properties of Manganese Ferrite Nanoparticles. International Journal of Engineering Research and Applications. 2014;4(8):14-17.. Those characteristics are in close connection with the magnetic structure, which is dependent on the magnetic cations, their distribution and concentration⁶6 Goldman A. Modern Ferrite Technology. New York: Springer; 2006.. The MnFe₂O₄ is an important member of spinel structured ferrite class due to their excellent properties such as high saturation magnetization, high initial permeability, high resistivity and low losses⁵5 Sharma US, Sharma RN, Shah R. Physical and Magnetic Properties of Manganese Ferrite Nanoparticles. International Journal of Engineering Research and Applications. 2014;4(8):14-17..

This system has a cubic spinel crystal structure with the unit cell consisting of eight units of the form [M_δFe_1-δ]^A [M_1-δFe_1+δ]^B O₄, where δ is a composition and acts as the inversion parameter with δ = 0 (1) standing for the inverse (normal) case. The 32 oxygen anions per unit cell form a face centered cubic cage, while the metallic cations occupy interstices. The metallic cations outside the bracket occupy the tetrahedral sites (A sites) comprising tetrahedral sublattice while those metallic cations enclosed by the bracket occupy octahedrally sites (B sites) comprising the octahedrally sublattice. Figure 1 shows a representation of the unit cell of the Mn-Cu ferrite. In tetrahedral (A) site, the interstice is in the centre of a tetrahedron formed by four lattice atoms. Four anions are occupied at the four corners of a cube and the cation occupies the body centre of the cubic-fcc. In octahedral sites (B), interstice is at the centre of an octahedron formed by 6 regular anions. The oxygen atom is represented by spheres⁶6 Goldman A. Modern Ferrite Technology. New York: Springer; 2006..

Figure 1
A fragment of the structure of Mn_0.50Cu_0.50 Fe₂O₄.

The spinel formation reaction by solid-state reaction is so slow because all of the ions Fe²⁺, Cu⁺², Mn⁺² diffuse slowly. Defects are formed, particularly vacancies adjacent sites at which ions can emerge. High temperatures for extended periods are necessary so that the ions have sufficient thermal energy to occasionally vibrate or jump from one site into an adjacent vacancy or interstitial⁷7 Zhang S, Lee W. Spinel-Containing Refractories. In: Schacht CA, ed. Refractories Handbook. New York: Marcel Dekker; 2004. p.215-258..

Both the cation distribution in the octahedral and tetrahedral sites and the grain size are crucial factors that determine the magnetic and electrical responses. The manganese ferrite is partial inverse spinel, where about 80% of Mn²⁺ ion occupy the tetrahedral A sites: However, there are Mn³⁺ ions at the octahedral B sites, and are connected by the presence of Fe²⁺ ions also present at these ionic sites. The addition of impurities induces changes in structure and texture of the crystal⁸8 Deraz NM, Alarifi A. Microstructure and Magnetic Studies of Zinc Ferrite Nano-Particles. International Journal Electrochemical Science. 2012;7:6501-6511.^,⁹9 Xiao Z, Shaohua J, Wang X, Li W, Wang J, Liang C. Preparation, structure and catalytic properties of magnetically separable Cu-Fe catalysts for glycerol hydrogenolysis. Journal of Materials Chemistry. 2012;32:16598-16605.. References⁹9 Xiao Z, Shaohua J, Wang X, Li W, Wang J, Liang C. Preparation, structure and catalytic properties of magnetically separable Cu-Fe catalysts for glycerol hydrogenolysis. Journal of Materials Chemistry. 2012;32:16598-16605.^,¹⁰10 Moulson AJ, Herbert JM. Electroceramics: Materials-Properties-Applications. 2nd ed. New Jersey: John Wiley & Sons Ltd; 2003. 576p. revealed that the magnetic performance and microstructure depend considerably on chemical composition and sintering temperature of samples.

With respect of electrical properties, it is desirable that a ferrite have as high resistivity as possible. This is necessary in order to avoid Foucault or Eddy currents that heat the material and loses energy, e.g. in a transformer. Improvements in contrast to conventional metallic ferromagnetic materials that present very strong Eddy currents, which leads to high operating temperatures¹¹11 Cullity BD. Elements of X-Ray Diffraction. Reading: Addison Wesley; 1956. are possible with Ferrite materials since the crystallite boundaries act as energy barriers, confining charge carriers, i.e. electrons, into the grains.

In this work, we have carried out alternating current (a.c.) and continuous current (c.c.) electrical and magnetical characterization of mixed manganese/copper ferrite. X-ray diffraction (XRD), a vibrating sample magnetometer (VSM), were used in this study.

2. Materials and Methods

The high purity oxides of Manganese (MnO), cupper (CuO) and iron (Fe₂O₃) were mixed and compacted up to a uniaxial press of 39 GPa. After, samples with chemical formula Mn_xCu_{1- x}Fe₂O₄ with manganese concentrations x of 0.40, 0.42, 0.44, 0.46, 0.48 and 0.50 were synthesized at 1000°C during 45 hours and finally heated to 1200°C by 5h, in room atmosphere. The crystalline phases were identified by means X-ray diffraction experiments using a Panalytical x'pert diffractometer, Cuk_α radiation, angular interval 2θ from 15° to 80°, angular step of 0.02 and 1 s counting time.

The crystallite size was calculated for all the compositions using the high intensity peak and Scherer formula¹¹11 Cullity BD. Elements of X-Ray Diffraction. Reading: Addison Wesley; 1956.:

(1)

L = \frac{0, 91 λ}{β \cos θ}

where L is the crystalline size perpendicular to (hkl) plane, λ the wavelength of X-ray used (λ = 1.5418 Å), β full width at half maximum of the diffraction peak (FWHM) and θ the peak angular position. The lattice parameters, a, were measured by Rietveld (FULLPROFF software). From EDX, the composition details of the prepared ferrites were determined.

The electronic conductivity was measured by Keithley 2400 source/measure unit and the temperature was varied in an oven with temperature control at a rate of 5 K/min up to a temperature of 573 K. The magnetic characterization was performed by means of a vibrating sample magnetometer Lakeshore model 7404. The magnetic parameters: coercive field H_c, saturation magnetization M_s, remanent magnetization M_R were determined by the hysteresis curves with an applied field of 12 kG. The Curie temperature were determined by the thermo-magneto-gravimetric technique. The a.c. electrical measurements were carried using an impedance analyzer in the frequency range 1 Hz to 10 MHz.

The graph ln (ρT^-1/2 vs. 1000/T indicates a large linear region associated to the grain/barrier model. The linearity occurs in two distinct temperature ranges, the E_b, N_d and L_D values obtained from to the slope of both linear fittings according to the equation (2).

(2)

E_{b} = \frac{{(L / 2)}^{2} e^{2} N_{d}}{8 {ε ε}_{0}}

where L is the average size of the crystallites determined from the Debye-Scherrer model (2), E_b is the energy barrier height at the grain boundary, N_d is the donor concentration, ε is the relative dielectric constant at low frequency and ε₀ is the vacuum permittivity. ε is determined as the asymptotic value calculated from a.c. impedance measurements at low frequency (determined in the range between 1Hz and 10Mhz) for all samples are shown in Table 2. This mechanism can be determined by Debye shielding length (L_D) with equation (3). If L_D <L/2, the potential barriers exist in the grain boundary region due to capture states at these interfaces¹²12 Mardare D, Iftimie N, Crisan M, Raileanu M, Yildiz A, Coman T, et al. Electrical conduction mechanism and gas sensing properties of Pd-doped TiO2 films. Journal of Non-Crystalline Solids. 2011;357(7):1774-1779..

(3)

L_{D} = \sqrt{(\frac{K_{B} T {ε ε}_{0}}{e^{2} N_{d}})}

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Table 1
Percentage of atomic elements of ferrites Mn_xCu_1-xFe₂O₄.

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Table 2
Parameters of the grain/barrier model for all Mn_xCu_1-xFe₂O₄ samples. x is the composition factor, the ε relative dielectric constant, the half of the average crystallite size (L/2), Debye shielding Length (L_D). The last two columns are related to the ability of carriers to cross such barriers, i.e. N_c the donor concentration and E_b the energy barrier height).

3. Results and Discussion

Figure 2 shows the X-ray diffractograms of the samples. Was observed peaks to Mn_xCu_1-xFe₂O₄ (0.40 < x < 0.50) ferrite correspond to standard spinel (JCPDS-file nº 01-074-2072) diffraction patterns which confirmed the cubic structure with no extra peaks corresponding to other phases. The peaks indexed to (111), (220), (311), (222), (400), (422), (511) and (440) planes of a cubic unit cell, all planes are the allowed planes which indicates the formation of cubic spinel structure in single phase¹³13 Mazen SA, Mansour SF, Zaki HM. Some physical and magnetic properties of Mg-Zn ferrite. Crystal Research &Technology. 2003;38(6):471-478..

Figure 2
X-ray diffraction (XRD) patterns of the ferrites with different compositions.

The Figure 3 shows the lattice parameter values of the ferrites as function of Mn-concentration. This figure shows that the "a" lattice parameter a increases with increasing Mn content due to the difference in the ionic radii between Mn²⁺ (0.66 Å) and Cu²⁺ (0.57 Å)¹⁴14 Shannon RD. Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides. Acta Crystallographica Section A. 1976;32(5):751-767.. The increase in lattice parameter with composition can be explained on the basis of Vegard's law ¹⁵15 Rana MU, Misbah-ul-Islam, Abbas T. Cation distribution in Cu-substituted manganese ferrites. Materials Letters. 1999;41(2):52-56.. This law explains the linear variation in lattice parameter with the ionic radii of the doped and the replacing ion. In the case we are replacing Mn²⁺ ion with Cu²⁺ ion. The lattice parameter is found to rise, which may be attributed to shifting on some Fe³⁺ ions form A site to B site for higher composition ¹⁶16 Whinfrey CG, Eckart DW, Tauber A. Preparation and X-Ray Diffraction Data for Some Rare Earth Stannates. Journal of the American Chemical Society. 1960;82(11):2695-2697.. The lattice parameters found are between a = 8.41 Å and a = 8.50 Å for copper and manganese ferrites, respectively. The value of the lattice parameter obtained for the all samples is in good agreement with reported in literature¹⁴14 Shannon RD. Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides. Acta Crystallographica Section A. 1976;32(5):751-767..

Figure 3
Lattice parameter as function of Mn-concentration for ferrites (0.40 < x < 0.50).

The EDX spectrum of Mn_xCu_{1- x}Fe₂O₄ (0.40 < x < 0.50) gave the information on the elemental composition of the material. The elemental compositions agree with the stoichiometric relations of the prepared compound. Table 1 presents the semi-quantitative results of EDS disregarding the presence of the element oxygen, because this element is very light (atomic mass 15,9994u ± 0,0004u). It shows the ratio of Mn/Cu experimental elements for each nominal composition of the samples.

The calculated values of crystallite size (L) for the distinct compositions are shown in Table 1. The value of crystallite size was calculated from Scherrer Formula by the high intensity peak (311). The values of L/2 range from 30 nm to 40 nm. These values are valid for the application of conduction model limited by potential barriers located at crystallite boundaries.

Figure 4 show the temperature dependence of the electrical resistivity by the d.c measurements for all ferrites samples. In all samples, it was found that the resistivity of the material rise as a function of inverse temperature. The crystallite boundaries with potential barriers model is the electrical conduction mechanism observed for all samples at high temperatures. For them, the high value of resistivity is associated with the simultaneous presence of ferrous and ferric ions on equivalent lattice sites¹⁷17 Smit J, Wijn HPJ. Ferrites. Eindhoven: Philips Technical Library; 1959. p.229-242..

Figure 4
Temperature dependence of electrical resistivity plotted as ln(ρT−1/2) vs. 103/T of samples Mn_xCu_1-xFe₂O₄.

In order to obtain parameters for Table 2, we considered one temperature in the center of both linear regions of Figure 4, i.e. T = 473 K.

As determined by the fitting parameters on Table 2, the electrical conductivity of all samples of mixed manganese/copper ferrite depends on boundaries. Since the barriers are high enough to avoid carriers to cross the crystallite boundaries and the low L_D confirms this fact we can conclude that the electrical transport in polycrystalline ferrites is dominated by those boundary effects. With energy barriers of about 0.5 eV, the Mn_xCu_{1- x}Fe₂O₄ ferrite samples presents a semiconductor behavior but with activation energies with the resistivity having a pre-exponent factor T^1/2, characteristic of conduction limited by potential barriers located at crystallite boundaries and confirmed by assuring L_D <L/ 2 relation.

Figure 5 shows the hysteresis loops at room temperature of all samples. We can observe that saturation is attained at relatively low fields (12 kG). It was possible to determine the values of some magnetic parameters such as the coercive field (Hc), remanent magnetization (Mr) and saturation magnetization (Ms). The results of measurement of the hysteresis of samples Mn_xCu_{1- x}Fe₂O₄ obtained from the hysteresis curves in Figure 5 are shown in Table 2.The samples were measured at room temperature and the magnetization was normalized considering the total sample mass.

Figure 5
Hysteresis loops at room temperature of samples Mn_xCu_1-xFe₂O₄. The inset corresponds to a zoom to help identifying the coercitive fields and remanent magnetization.

The Mn-Cu ferrites have a supermagnetic behavior trend that is observed by the magnetization curve (Figure 5). The variation of saturation magnetization can be correlated to the distribution of cations due to the exchange interaction of tetrahedral (A) and octahedral (B) ions. The molecular magnetization (M) is given by the difference between magnetization of MB and MA octahedral and tetrahedral sites, respectively, in which subnet B has a higher magnetization. Since Cu²⁺ ions have a magnetic moment less than Mn²⁺ ions, the replacement of Cu²⁺ ions by Mn²⁺ ions in octahedral sites should result in increased M_S.

The results of saturation magnetization as a function of manganese concentration are shown in Table 3 and can be identified also on Figure 5. There was an increase in the value of saturation magnetization with increasing manganese of x=0.40 to 0.46 and x = 0.40 to 0.46 there is a decrease in saturation magnetization in the system Mn_xCu_1-xFe₂O₄. This is attributed to decrease in magnetization of the sublattice B. This is achieved by two mechanisms, i.e. both the reduction of the magnetization of the sublattice B due to the existence of Cu²⁺ with less time or more Mn²⁺ ions occupy the A sites, and more Fe³⁺ ions are forced to migrate to A sites. Thus, the result is a decrease in the magnetic moment of the sublattice B¹⁸18 Azab A, EL-Khawas EH. Synthesis and Magnetic anomalies of Copper Manganese ferrite Mn1-xCuxFe2O4 (0.0 =x = 0.7). Journal of Applied Sciences Research. 2013;9(3):1683-1689.. For samples with higher copper content, most Cu²⁺ occupies the octahedral sites and disturbs the ferromagnetic interactions between Fe³⁺ions¹⁹19 Cao JG, Li JJ, Duan HF, Lin YJ. Synthesis and Characterization of Manganese-copper Spinel Ferrite Powders. Chemical Research in Chinese Universities. 2012;28(4):590-593..

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Table 3
Results for the hysteresis measurements of samples MnxCu1-xFe2O4

With all these characterization techniques we infer that the ceramics exhibited characteristics of a soft magnetic material with high electric resistivity.

4. Conclusion

Mn_xCu_{1- x}Fe₂O₄ ferrite (0.40 < x < 0.50) were synthesized by a conventional solid-state reaction method and investigated as potential materials for devices electronic and drug delivery. The system Mn_xCu_{1- x}Fe₂O₄ is single phase spinel ferrite with cubic unit cell for all compositions. The X-ray analysis confirmed the formation of the single phase samples for the compositions 0.40 < x < 0.50 and shown that the lattice parameter "a" increase linearly with increase Mn content, due to the ion substitution. A typical magnetization versus magnetic field (M-H) curve of Mn_xCu_1xFe₂O₄ ferrite collected on a VSM shows an increase in magnetization as the magnetic field increases. The magnetization versus magnetic field curves collected are characteristic of soft magnetic materials. These mixed spinel ferrites are useful as magnetic devices due to low coercivity field H_C and high saturation magnetization. In the study of manganese/copper ferrite, the resistivity is found to be decreased with increasing temperature for all samples. The ferrites show semiconducting behavior with conduction in crystallites with potential barriers located at crystallite boundaries as defined by x-ray data and calculations of Debye length. We have shown that electron transport in the investigated samples is dominated by grain/barrier model adapted to this crystallite scenario at high temperatures (T=423 K).

5. Acknowledgments

The authors are grateful to the Brazilian agencies, National Counsel of Technological and Scientific Development (CNPq), Coordination for the Improvement of Higher Level -or Education- Personnel (CAPES) and Foundation for Research Support of the State of Minas Gerais (FAPEMIG).

6. References

¹
Chen D, Liu HY, Li L. One-step synthesis of manganese ferrite nanoparticles by ultrasonic wave-assisted ball milling technology. Materials Chemistry and Physics 2012;134(2-3):921-924.
²
Kumar ER, Jayaprakash R, Devi GS, Reddy PSP. Synthesis of Mn substituted CuFe2O4 nanoparticles for liquefied petroleum gas sensor applications. Sensors and Actuators B: Chemical 2014;191:186-191.
³
Kumar ER, Jayaprakash R, Devi GS, Reddy PSP. Magnetic, dielectric and sensing properties of manganese substituted copper ferrite nanoparticles. Journal of Magnetism and Magnetic Materials 2014;355:87-92.
⁴
Rosales MI, Plata AM, Nicho ME, Brito A, Ponce MA, Castaño VM. Effect of sintering conditions on microstructure and magnetic properties of Mn-Zn ferrites. Journal of Materials Science 1995;30(17):4446-4450.
⁵
Sharma US, Sharma RN, Shah R. Physical and Magnetic Properties of Manganese Ferrite Nanoparticles. International Journal of Engineering Research and Applications 2014;4(8):14-17.
⁶
Goldman A. Modern Ferrite Technology New York: Springer; 2006.
⁷
Zhang S, Lee W. Spinel-Containing Refractories. In: Schacht CA, ed. Refractories Handbook New York: Marcel Dekker; 2004. p.215-258.
⁸
Deraz NM, Alarifi A. Microstructure and Magnetic Studies of Zinc Ferrite Nano-Particles. International Journal Electrochemical Science 2012;7:6501-6511.
⁹
Xiao Z, Shaohua J, Wang X, Li W, Wang J, Liang C. Preparation, structure and catalytic properties of magnetically separable Cu-Fe catalysts for glycerol hydrogenolysis. Journal of Materials Chemistry 2012;32:16598-16605.
¹⁰
Moulson AJ, Herbert JM. Electroceramics: Materials-Properties-Applications 2nd ed. New Jersey: John Wiley & Sons Ltd; 2003. 576p.
¹¹
Cullity BD. Elements of X-Ray Diffraction Reading: Addison Wesley; 1956.
¹²
Mardare D, Iftimie N, Crisan M, Raileanu M, Yildiz A, Coman T, et al. Electrical conduction mechanism and gas sensing properties of Pd-doped TiO₂ films. Journal of Non-Crystalline Solids 2011;357(7):1774-1779.
¹³
Mazen SA, Mansour SF, Zaki HM. Some physical and magnetic properties of Mg-Zn ferrite. Crystal Research &Technology 2003;38(6):471-478.
¹⁴
Shannon RD. Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides. Acta Crystallographica Section A 1976;32(5):751-767.
¹⁵
Rana MU, Misbah-ul-Islam, Abbas T. Cation distribution in Cu-substituted manganese ferrites. Materials Letters 1999;41(2):52-56.
¹⁶
Whinfrey CG, Eckart DW, Tauber A. Preparation and X-Ray Diffraction Data for Some Rare Earth Stannates. Journal of the American Chemical Society 1960;82(11):2695-2697.
¹⁷
Smit J, Wijn HPJ. Ferrites Eindhoven: Philips Technical Library; 1959. p.229-242.
¹⁸
Azab A, EL-Khawas EH. Synthesis and Magnetic anomalies of Copper Manganese ferrite Mn_1-xCu_xFe₂O₄ (0.0 =x = 0.7). Journal of Applied Sciences Research 2013;9(3):1683-1689.
¹⁹
Cao JG, Li JJ, Duan HF, Lin YJ. Synthesis and Characterization of Manganese-copper Spinel Ferrite Powders. Chemical Research in Chinese Universities 2012;28(4):590-593.

Publication Dates

Publication in this collection
31 May 2016
Date of issue
Jul-Aug 2016

History

Received
31 Aug 2015
Reviewed
21 Dec 2015
Accepted
10 May 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Chen D, Liu HY, Li L. One-step synthesis of manganese ferrite nanoparticles by ultrasonic wave-assisted ball milling technology. Materials Chemistry and Physics 2012;134(2-3):921-924.

[2] ²
Kumar ER, Jayaprakash R, Devi GS, Reddy PSP. Synthesis of Mn substituted CuFe2O4 nanoparticles for liquefied petroleum gas sensor applications. Sensors and Actuators B: Chemical 2014;191:186-191.

[3] ³
Kumar ER, Jayaprakash R, Devi GS, Reddy PSP. Magnetic, dielectric and sensing properties of manganese substituted copper ferrite nanoparticles. Journal of Magnetism and Magnetic Materials 2014;355:87-92.

[4] ⁴
Rosales MI, Plata AM, Nicho ME, Brito A, Ponce MA, Castaño VM. Effect of sintering conditions on microstructure and magnetic properties of Mn-Zn ferrites. Journal of Materials Science 1995;30(17):4446-4450.

[5] ⁵
Sharma US, Sharma RN, Shah R. Physical and Magnetic Properties of Manganese Ferrite Nanoparticles. International Journal of Engineering Research and Applications 2014;4(8):14-17.

[6] ⁶
Goldman A. Modern Ferrite Technology New York: Springer; 2006.

[7] ⁷
Zhang S, Lee W. Spinel-Containing Refractories. In: Schacht CA, ed. Refractories Handbook New York: Marcel Dekker; 2004. p.215-258.

[8] ⁸
Deraz NM, Alarifi A. Microstructure and Magnetic Studies of Zinc Ferrite Nano-Particles. International Journal Electrochemical Science 2012;7:6501-6511.

[9] ⁹
Xiao Z, Shaohua J, Wang X, Li W, Wang J, Liang C. Preparation, structure and catalytic properties of magnetically separable Cu-Fe catalysts for glycerol hydrogenolysis. Journal of Materials Chemistry 2012;32:16598-16605.

[10] ¹⁰
Moulson AJ, Herbert JM. Electroceramics: Materials-Properties-Applications 2nd ed. New Jersey: John Wiley & Sons Ltd; 2003. 576p.

[11] ¹¹
Cullity BD. Elements of X-Ray Diffraction Reading: Addison Wesley; 1956.

[12] ¹²
Mardare D, Iftimie N, Crisan M, Raileanu M, Yildiz A, Coman T, et al. Electrical conduction mechanism and gas sensing properties of Pd-doped TiO₂ films. Journal of Non-Crystalline Solids 2011;357(7):1774-1779.

[13] ¹³
Mazen SA, Mansour SF, Zaki HM. Some physical and magnetic properties of Mg-Zn ferrite. Crystal Research &Technology 2003;38(6):471-478.

[14] ¹⁴
Shannon RD. Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides. Acta Crystallographica Section A 1976;32(5):751-767.

[15] ¹⁵
Rana MU, Misbah-ul-Islam, Abbas T. Cation distribution in Cu-substituted manganese ferrites. Materials Letters 1999;41(2):52-56.

[16] ¹⁶
Whinfrey CG, Eckart DW, Tauber A. Preparation and X-Ray Diffraction Data for Some Rare Earth Stannates. Journal of the American Chemical Society 1960;82(11):2695-2697.

[17] ¹⁷
Smit J, Wijn HPJ. Ferrites Eindhoven: Philips Technical Library; 1959. p.229-242.

[18] ¹⁸
Azab A, EL-Khawas EH. Synthesis and Magnetic anomalies of Copper Manganese ferrite Mn_1-xCu_xFe₂O₄ (0.0 =x = 0.7). Journal of Applied Sciences Research 2013;9(3):1683-1689.

[19] ¹⁹
Cao JG, Li JJ, Duan HF, Lin YJ. Synthesis and Characterization of Manganese-copper Spinel Ferrite Powders. Chemical Research in Chinese Universities 2012;28(4):590-593.

Sample	Mn	Cu	Fe	Mn/Cu
Sample	(%)	(%)	(%)	(%)
MCF 40	12.45±0.32	20.28±0.52	65.3±1.4	38.04±0.14
MCF42	14.34±0.34	19.75±0.54	65.9±1.4	42.06±0.18
MCF44	14.74±0.36	18.67±0.52	66.6±1.5	44.12±0.19
MCF46	13.83±0.37	19.79±0.52	66.4±1.4	46.84±0.17
MCF48	15.37±0.33	17.00±0.53	67.4±1.5	47.48±0.20
MCF50	16.20±0.29	16.63±0.58	67.2±1.4	49.34±0.21

x	ε	L/2(nm)	L_D(nm)	N_c (10¹⁷ cm^-3)	E_b (eV)
0.40	22.9	38.76	6.90	9.20	0.44
0.42	37.5	34.76	6.76	15.7	0.45
0.44	28.9	32.94	6.44	13.3	0.47
0.46	21.2	32.09	6.57	9.39	0.49
0.48	30.7	32.41	5.87	17.0	0.43
0.50	18.6	37.13	7.97	5.59	0.49

x	M_s (emu/g)	M_r (emu/g)	H_c (G)	M_s/M_r	Tc (K)
0.40	53.94±0.05	3.847±0.004	23.132±0.002	14.02	636
0.42	55.20±0.06	3.989±0.004	26.114±0.003	13.84	633
0.44	55.63±0.06	2.500±0.002	16.468±0.002	22.25	632
0.46	56.06±0.06	6.349±0.006	16.337±0.002	8.83	631
0.48	54.16±0.05	3.849±0.004	25.902±0.003	14.07	624
0.50	53.08±0.05	2.844±0.003	22.98±0.002	18.66	632

Brasil

Brasil

Magnetic and Electrical Properties of Mn_xCu_1-xFe₂O₄ Ferrite

Abstract

1. Introduction

2. Materials and Methods

3. Results and Discussion

4. Conclusion

5. Acknowledgments

6. References

Publication Dates

History