- Open Access
- Total Downloads : 792
- Authors : Swati Gupta, Suruchi Singh, Dr. Pankaj Sharma
- Paper ID : IJERTV2IS4710
- Volume & Issue : Volume 02, Issue 04 (April 2013)
- Published (First Online): 29-04-2013
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Doping Effect of Nickel on Cobalt Ferrite at Varying Temperatures: Synthesis and Morphology Studies
Swati Gupta, Suruchi Singh, Dr. Pankaj Sharma
Department of Material Science ,Jaypee University of Information Technology, Waknaghat, Solan, H.P. (173234) India
Abstract–Nickel doped cobalt ferrite magnetic nano-particles were synthesized in a homogeneous aqueous solution by wet chemical method. Samples were characterized by X-ray diffraction (XRD) and transmission electron microscopy (TEM). Effects on structural properties as a function of sintering temperature and nickel dopant have been investigated. Changes in the particle size, strain and dislocation density were observed with temperatures. The morphology of nickel doped cobalt ferrite was analyzed by TEM which showed a crystalline cubic structure.
INTRODUCTION
Ferrites are engineering resources with Fe2O3 as their key constituent and find popular applications in microwave and magneto-optical technologies ([1]-[5]). The soft ferrites are mainly utilized for high frequency inductors and transformers. Hard ferrites, on the other hand, have high coercivity and high remanence are extensively used for making permanent magnets. Cobalt ferrite (CoFe2O4) is a well-known hard ferrite with high coercivity and moderate magnetization with excellent chemical stability and good mechanical hardness [6].These properties, in conjunction with great physical and chemical constancy, make cobalt ferrite (CoFe2O4) nanoparticles appropriate resources for imaging, spin electronics devices, magnetic recording and sensor applications ([7], [8]). However, adding impurity in cobalt ferrites alters its properties [9]. The magnetic characteristics of the particles meant for recording media depends on the size, shape, and purity of nanoparticles. Synthesis process should be comparatively simple and controls particle size with
high yield. Synthesis techniques of nanoparticles include evaporation condensation, sol-gel processing ([10], [11]), hydrothermal method [12], reverse micelles [13], thermal treatment ([14], [15]), micro emulsions [16], laser-induced vapour phase reactions and aerosols ([17]-[19]). In this research the nickel doped cobalt ferrite nano-particles were synthesized by wet chemical method (co- precipitation). The obtained samples were sintered at different temperatures (100 0C, 400 0C and 600 0C) and characterized using X-ray diffraction (XRD) and transmission electron microscopy (TEM).
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Experimental details
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MATERIALS
Iron (III) chloride hexahydrate (FeCl3.6H2O); cobalt (II) chloride hexahydrate (CoCl2.6H2O); nickel (II) chloride hexahydrate (NiCl2.6H2O); sodium hydroxide pellets (NaOH). All the materials were AR grade (Merck India) and were used as received. Double distilled water was used as a solvent.
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SYNTHESIS
Stocks of aqueous solution of iron chloride and cobalt chloride were prepared in 2:1 ratio and then mixed under constant stirring with the help of a magnetic stirrer and heated
to 60 0 C. NaOH solution was slowly added to the salt solution drop wise until a pH level of 12 reached. Black precipitates appeared in the solution then the solution was kept at 80 0C for one hour with constant stirring. The precipitates were then washed twice with double distilled water and then with ethanol to get nanoparticles free from sodium and chlorine ions. The supernatant liquid was decanted after centrifugation until only thick black precipitates remained. The precipitates
0
140
120
311
311
100
intensity
intensity
80
440
440
220
220
511
511
60
40
400
400
222
222
333
333
533
533
were then dried for twelve hours at 100 C. The obtained
samples were then grinded into a fine powder. The samples were sintered at 400 0C and 600 0C for ten hours each. Finally, blackish powder of cobalt ferrite was obtained. Magnetic nature of powder was checked using bar magnet.
Similarly, Nickel doped Cobalt ferrite had been synthesized and heat treated. Co(1-x)NixFe2O4 is general chemical formula used for doping where x = 0.1 M aqueous solution of nickel chloride. 0.2 M aqueous solution of cobalt (II) chloride and
0.6 M aqueous solution of Iron (III) chloride was prepared and mixed with 0.1 M aqueous solution of nickel (II) chloride at 60 0C. The overall reaction is supposed to be
CoCl2.6H2O + NiCl2.6H2O +10NaOH + 2FeCl3.6H2Oa Co(1-x)NixFe2O4 + 10NaCl +28H2O
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Characterization
X-ray diffractometer (XRD) (Panalytical's X'Pert Pro) has Cu-Ka radiation (1.54 Ã…). Goniometer = PW3050/60 (Theta/Theta); Minimum step size 2Theta:0.001; Minimum step size Omega: 0.001 was used to study structural parameters. Transmission electron microscopy (Hitachi, H- 7500, 40-120 kV operating voltage) images of material were obtained at 90 kV.
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Results and Discussion
The fig.1 (a) and 1 (d) corresponds to temperature 100 0C , confirming the formation of cobalt ferrite and nickel doped cobalt ferrite respectively.
20
444
444
422
422
0
30 35 40 45 50 55 60 65 70 75 80
2 Theta
Fig1 (a): XRD Pattern of cobalt ferrite at 100C
The crystal structure of the CoFe2O4 has a cubic symmetry (JCPDS card No. 22-1086). In fig.1 (a) three broad lightly intense peaks at (311), (440) and (422) plane were observed confirming the formation of the nanoparticles here with peak at (220) and (440) revealing formation of CaO and CaO3.
While fig.1(b) for 400 0C contains more intense peaks,
observed at (311), (400), (411), (422), (440), (511) showing the formation of fine particles at 400 0C but in fig. 1(d) the peak at (220) is much intense showing formation of oxide in large amount, and for 6000C fig.1(c) gives sharp peaks of (311), (400), (411), (422), (440), (511) planes.
340
331
331
320
300
280
260
240
220
440
440
Intensity
Intensity
200
180
160
140
120
220
220
400
400
333
222
333
222
100
80
533
533
60
422
422
444
444
40
20
0
25 30 35 40 45 50 55 60 65 70 75 80
2 Theta
Fig1 (b): XRD Pattern of cobalt ferrite at 400C
Comparing fig.1 (a-c) all peaks becomes more intense and sharp with increasing sintering temperature i.e., crystalline nature is increasing.
140
120
100
intensity
intensity
80
60
40
20
0
220
311
400
222
422
333
511
440
533
444
240
311
311
220
200
180
160
Intensity
Intensity
140
120
100
440
440
80
220
220
511
440 422 333
511
440 422 333
60
40
222 533
222 533
20
30 35 40 45 50 55 60 65 70 75 80
2 Theta
0
25 30 35 40 45 50 55 60 65 70 75 80
2 Theta
140
120
100
Intensity
Intensity
80
60
Fig1(c): XRD Pattern of cobalt ferrite at 600C
222
222
311
311
Fig1 (f): XRD Pattern of nickel doped cobalt ferrite at 600C
There are some extra peaks in fig.1 (e) and fig. 1(f) showingimpurity in the nano powder. A comparison fig. 1(a –
f) shows peaks becoming intense and sharp for 400 0C.
Grain size of the nano-crystallite calcined powder was calculated using the Scherers formula [21].
333
333
440
440
k
D
220
220
422
422
511
511
40 cos
(1)
400
400
533
533
20
0
25 30 35 40 45 50 55 60 65 70 75 80
2 Theta
Fig1 (d): XRD Pattern of nickel doped cobalt ferrite at 100C
140
120
222
222
100
Intensity
Intensity
80
311
311
60
where D is the grain size, is the wavelength of X-ray radiation, is Braggs angle, is the full width at half maxima of the most intense diffraction peak, and k is the instrumental constant, which is 0.94. Average particle size of cobalt ferrite nano particle was observed to be in the range 40 nm to 90 nm for samples at 100 0C, 400 0C, 600 0C. But with addition of nickel impurity it gets reduced from 20 nm to 50 nm for samples at 100 0C, 400 0C, 600 0C.
From XRD data of the powder sample, some important parameters of the prepared sample have been calculated, such as lattice parameter, strain of the crystal and dislocation density. The average strain of the sample calculated by Stokes Wilson equation [22]
333
333
440
440
220
220
422
422
511
511
40
4 cos
(2)
400
400
533
533
20
0
25 30 35 40 45 50 55 60 65 70 75 80
2 Theta
Fig1 (e): XRD Pattern of nickel doped cobalt ferrite at 400C
Average strain increases with addition of nickel to cobalt ferrite (Table 1).
Dislocation density calculated [23] corresponding to Figure 1([a]-[f]).
15 (3)
aD
where D is average grain size, a is lattice parameter [24].
a d
h 2 k 2 l 2
(4)
where spacing between two planes is d, calculated values for lattice parameters are increasing due to doping (Table 1). We observed that the lattice parameters depend on the nickel doping as well as on heat treatment.
Temperature (O C)
Particle Size(Nm)
Strain
Lattice Parameters (Ã…)
Dislocation Density
100
58.7
6.60 x 10-4
16.41
1.02 x 1014
400
92.3
4.4 x 10-4
18.24
3.9 x 1014
600
44.0
8.8 x 10-4
16.98
1.78 x 1014
doped sample at 100
18.3
21.33 x 10-4
16.58
1.94 x 1014
doped sample at 400
44.59
8.8 x 10-4
16.25
1.8 x 1014
doped sample at 600
29.3
13.33 x 10-4
16.38
4.5 x 1014
Table 1 Lattice Parameter, Strain and Dislocation Density at 100C, 400C,
600C
The morphology and particle size of nickel doped cobalt ferrite nano particles was determined by TEM.
Fig2 (a): TEM image of cobalt ferrite at 400C
Fig2 (b): TEM images of nickel doped cobalt ferrite at 400C.
The TEM micrograph for CoFe2O4 powder is shown in Fig. 2. The TEM micrograph of the powder sample at 4000C
in fig. 2 (a) and fig. 2 (b) shows that the particles are cubic in nature and with doping the particle size decreases.
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CONCLUSION
Nickel doped cobalt ferrite nanocrystallite has been successfully synthesized at pH 11-12 in a range of temperature (100, 400, 6000C) by co-precipitation route. Change in structural characteristics and morphology due to doping were observed by XRD and TEM, respectively. XRD pattern showed that nanocrystallite of cobalt ferrite decreased when doped with nickel. The TEM images showed that grains were regular cubic shaped nanoparticles.
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