Dongying Niu, Jinku Yu, Qi Qiao, Dongdong Wang, Runhai Liu
State Key Laboratory of Metastable Materials Science and Technology, Yanshan University, Qinhuangdao, China..
DOI: 10.4236/jsemat.2012.23026   PDF    HTML   XML   3,746 Downloads   6,163 Views   Citations

Abstract

To improve the oxidation resistance property of iron fibers, a SiO₂ coated iron fiber was prepared by sol-gel method, and its microstructure, element and phase composition, antioxidation property, and crystallization were characterized by scanning electron microscopy, thermal gravimetric analysis, X-ray diffraction and 3% CuSO₄ solution dripping. It was found that the surface of the iron fiber can be fully covered with SiO2 by using Sol-Gel method. Our results also indicated that the time of iron begin to be corrupted in 3% CuSO4 solution drip increased from 30 s to 240 s, and the temperature increased from 200?C to 310?C. In addition, the oxidation and antioxidation mechanisms of the SiO2 coated iron fiber have also been discussed in this work.

Keywords

Corrosion Resistance; Anti-Oxidation; Sol-Gel Method; SiO₂

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1. Introduction

Up to now, the most commonly used microwave absorbers are magnetic materials (such as ferrite particles) and dielectric materials (such as carbon black particles) [1-3]. However, the expansion of applications was limited due to their thickness and weight. Recently, some researchers has been devoted to the study of the electromagnetic properties of nonspherical magnetic materials [4-8], such as iron fibers (MIFs) etc. Owing to MIFs’ unique properties, lower cost and important applications as functional microwave absorbing materials, the preparation and properties of MIFs have been investigated by many researchers [9,10]. To date, MIFs can be produced by bundle-drawing, melt-extraction, and chatter-machining [7, 11-16] methods. For example, MIFs with diameter less than 2 μm have been prepared by using bundle-drawing method [7]. However, the MIFs easily oxidized in air, and this poor anti-corrosion ability prevents its wide applications. To overcome this disadvantage, many methods have been used to improve the anti-corrosion ability of the MIFs [17]. However, the anti-corrosion ability is not good enough. Therefore, a new technique is necessary to develop to improve the anti-corrosion ability of MIFs.

The sol-gel technique is a low-temperature route widely employed to prepare thin films for use in the different fields, because it can offer the homogeneous thin films at molecular scale and control of chemical purity. Recently, it has a rapid development in the field of machining electromagnetic materials and the interest to prepare the materials by sol-gel methods [18-19] has increased remarkably. Moreover, SiO₂ has excellent insulation property and antioxidation property. To this end, a novel SiO₂ coated MIFs has been developed by sol-gel technique in this paper. Our experimental results further demonstrated that the antioxidation property of the SiO₂ coated MIFs has been improved evidently.

2. Experimental Methods

In this work, silicon dioxide sols were prepared by using tetraethoxysilane (TEOS) as precursor, ammonia water as activator and absolute alcohol as solvent. Firstly, 100 ml TEOS/alcohol solution was prepared by mixing TEOS with absolute ethanol at a molar ratio 3:10 of TEOS to C₂H₅OH, and then 50 ml ammonia water was added into the TEOS/alcohol solution smoothly under stirring simultaneously. After that, 10 g iron fibers were added into the above prepared solution, at the same time, the system was kept shaking and the temperature was kept at 25˚C in water shaker for 30 min. Finally, the iron fibers were dried in oven at 100˚C, and a SiO₂ coated MIFs were obtained.

For passivation, a solution of chromiumtrioxide/ phosphoric acid/blackening agent/accelerant was prepared with molar ratio of 6:3:4:15 and the amount of the reagents in solution were varied in the range 20 - 35 g. Then put the above treated MIFs into the passivation solution and passivating for 4 hours at 25˚C. After that, the final passivated MIFs were washed with distilled water and then dried in air at 60˚C.

To characterize the final obtained MIFs, scanning electron microscopy (SEM), thermal gravimetric analysis (TGA), X-ray diffraction (XRD) and 3% CuSO₄ solution dripping were used. In detail, SEM was used to observe the morphology of the films. Elements of the passivated films are conformed by using energy dispersive spectrum (EDS). Phase composition of the passivated films after heat treatment was identified by XRD. The thermal behavior of the samples was determined by TGA. 3% CuSO₄ solution drip was adopted to determine the anticorrosion property of the passivated films.

3. Results and Discussion

To study the morphology of MIFs before and after solgel processing, SEM is performed for the MIFs samples, and they are shown in Figure 1. The SEM images of the MIFs before and after treatment are shown in Figures 1(a) and (b), respectively. As can be seen from Figure 1, the surface of the MIFs without treatment was rough and full of drawing trace, which can improve the physics limitation and easily been corrupted. As shown in Figure 1(b), after sol-gel processing, the surface of the MIFs has been covered with SiO₂ successfully.

In order to investigate the morphology of SiO₂ coated MIFs after passivation, SEM is also perform for SiO₂ coated MIFs after passivation, and shown in Figure 2. As can be seen from Figure 2, the surface of the MIFs has been covered with spherical SiO₂ particles.

In this work, element distribution is also characterized by EDS for the SiO₂ coated MIFs and the results are shown in Figure 3. It can be seen from Figure 3, besides of the peaks corresponding to Ni, C, O, Cu elements, there are several characteristic peaks of Fe element, which attributed to the iron fibers. The Si, O elements comes from the sol-gel method, and the Ni elements are obtained from the passivation. This result further indiated that the surface of the MIFs has been coated with SiO₂ successfully, and this further confirms our previous SME results.

In order to study the oxidation resistance property of MIFs after sol-gel processing and passivation, TGA experiments are performed for MIFs before and after solgel processing and passivation, and they are shown in Figure 4. It is found that the weight begin to increase at 200˚C for MIFs without treatment, this means that the MIFs without treatment began to oxidize at this point. When the temperature reaches to 370˚C, the MIFs start to aggravate. Compared to the MIFs without treatment, the temperature for the treated MIFs begin to oxidize is 310˚C, and the aggravate temperature is 440˚C. Meanwhile, the increased weight of the treated MIFs is always less than the MIFs without treatment. These results indicate that the oxidation resistance of the MIFs is enhanced after sol-gel processing and passivation evidently.

To further study the oxidation resistance property and phase stability of MIFs after sol-gel processing and passivation, XRD experiments are performed for MIFs sample after heat treatment under 400˚C for 3 hours, and they are shown in Figure 5. In this work, two kinds of MIFs samples were heat treated, one is the MIFs sample just after sol-gel processing, and the other one is the MIFs sample after both sol-gel processing and passivation treatment. It can be concluded from Figure 5, after heat treatment under 400˚C for 3 hours, the XRD pattern of the MIFs sample just after sol-gel processing exists two main phases: pure iron and Fe₃O₄. But for the XRD pattern of the MIFs sample after both sol-gel processing and passivation treatment exist only one main phase: pure iron. These results imply that the oxidation resistance property of the sol-gel processing treated MIFs can be further improved by passivation processing. Our present results also consist with the previous TGA study, and further confirmed our previous experiments. The anticorrosion property of the MIFs was identified by 3% CuSO₄ solution drip and the result turns up to be: the anti-corrosion time of the MIFs after treatment increased from 65 s to 240 s.

4. Conclusion

In order to improve the oxidation resistance property of MIFs, a novel SiO₂ coated MIFs has been developed, and to further improve the oxidation resistance property of MIFs, a passivation processing was studied. The experimental results indicated that, the surface of the MIFs can be covered by SiO₂ after sol-gel processing. The antioxidation property of SiO₂ coated MIFs can be improved by further passivation treatment.

5. Acknowledgements

The authors gratefully acknowledge the support of the SIWEITE metal fibers company for providing the MIFs. Thanks are also made to Professor J. K. Yu and M. Z. Wang for help with experiments and valuable discussions.

NOTES

Conflicts of Interest

The authors declare no conflicts of interest.

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