Abstract
The graphene/CoFe2O4/Y3Fe5O12 nanocomposite were successfully synthesized by a deoxidation technique. The phase composition, morphology and electromagnetic properties of the composites were characterized by X-ray diffractometer, scanning electron microscope, X-ray photoelectron spectroscopy, Raman spectra, and vector network analyzer. The electromagnetic parameters of the graphene/CoFe2O4/Y3Fe5O12 nanocomposite were investigated in the 2–18 GHz range. The experimental results show that the graphene/CoFe2O4/Y3Fe5O12 nanocomposite exhibits evidently enhanced microwave absorbing performance in comparison with the CoFe2O4/Y3Fe5O12 nanocomposite. An effective absorption band is obtained by graphene/CoFe2O4/Y3Fe5O12 nanocomposite at 14–16 GHz and the maximum reflection loss is −36.1 dB at 14.88 GHz.
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1 Introduction
Microwave absorbing materials have attracted much attention due to their great potential in civilian application including protection people from electromagnetic radiation and their military purposes, such as radar invisible aircrafts, bombs and tanks [1,2,3]. Therefore, excellent microwave absorbing materials are required to be lightweight with strong absorption and broad absorption bandwidths. In recent years, conducting polymers, carbon nanotubes, ferrites, etc. have been developed to attenuate electromagnetic wave [4,5,6,7].
Ferrites, as magnetic materials, have become a hot topic due to their low cost, environmental stability, high saturation magnetization and magnetic loss. The fundamental magnetic properties of Y3Fe5O12 originates from the magnetic ions and their relationship to the surrounding oxygen ions. Y3Fe5O12 has attracted much attention as memory materials and microwave device [8]. Simultaneously, the spinel ferrites CoFe2O4 have strong anisotropy, high saturation magnetization and moderate coercivity at room temperature [9]. However, ferrite absorbers have higher density and lower dielectric loss which restrain their wide applications as microwave absorbers. To overcome these shortcomings, dielectric loss fillers such as conduction polymers, graphene are always added into the system. Recently, graphene has grabbed considerable attention for microwave absorption due to the residual defects, the large aspect ratio, interfacial polarizations and high conductivity [10, 11].
In our work, the CoFe2O4/Y3Fe5O12 nanocomposite powders were successfully synthesized by a sol–gel method, and then the CoFe2O4/Y3Fe5O12 was deposited on the surface of graphene sheets. The samples can obtain good electrical conductivity and electromagnetic properties, achieving the optimized microwave absorption property.
2 Experimental procedure
2.1 Preparation of graphite oxide (GO)
GO was prepared by modified Hummers’ method [12]. In a typical preparation, 2 g portion of natural flake graphite with 2 g of NaNO3, and 96 ml of concentrated H2SO4 were stirred together in an ice water bath, and then 12 g of KMnO4 was slowly added to the above mixture for 1.5 h. After that, the solution was moved to a 35 °C water bash and went on stirring for about 2 h to form a thick paste. 80 ml of distilled water was slowly added into the above paste and the resulting solution was stirred for 30 min while the temperature was raised to 90 °C. Finally, 200 ml of water containing 10 ml of H2O2 was added for 10 min until the color of the solution turned from dark brown to yellow. The graphite oxide deposit was collected from the graphite oxide suspension by high-speed centrifugation, and repeatedly washed with distilled water until the pH value is 7 and then dried at 60 °C.
2.2 Preparation of 0.7CoFe2O4/0.3Y3Fe5O12
CoFe2O4/Y3Fe5O12 nanocomposite powder with a mass ratio of 3:7 was synthesized by a one-step sol–gel method. The aqueous solution was prepared by dissolving Y(NO3)2·6H2O, and Fe(NO3)3·9H2O, Co(NO3)2·6H2O, and C6H8O7·H2O into distilled water and magnetically stirred at 80 °C. Ammonia was added to the above solution to adjust the pH value to 7. After that the mixture solution was dried at 200 °C for 2 h, the black floppy carbonaceous precursor powders were obtained. Finally, the precursor powders were calcined at 1100 °C for 4 h to obtain the 0.7CoFe2O4/0.3Y3Fe5O12 nanocomposite powder.
2.3 Preparation of graphene/0.7CoFe2O4/0.3Y3Fe5O12
Graphene/0.7CoFe2O4/0.3Y3Fe5O12 nanocomposite powder was prepared with the mass ratio of GO and 0.7CoFe2O4/0.3Y3Fe5O12 is 1:5. In the first step, a certain amount of GO were dispersed in glycol by ultrasonication for 4 h. And then the 0.7CoFe2O4/0.3Y3Fe5O12 nanocomposite powder was added into the suspension. The suspension continued dispersing by ultrasonication for 1 h. After that, the mixture was reacted at 200 °C for 24 h by a hydrothermal method. The resulted precipitate was filtrated, washed with distilled water and ethanol repeatedly and dried under vacuum at 50 °C for about 24 h.
2.4 Characterization
The phase composition of the samples was detected by an X-ray diffractometer (XRD) with Cu Kα radiation (Rigaku D/MAX-2400, Japan). The scanning electron microscope (SEM) (Hitachi S-4800, Japan) equipped with an energy dispersive X-ray spectroscopy (EDS). The chemical states were investigated by X-ray photoelectron spectroscopy (XPS, PHI 5300X). The Raman spectra of the nanocomposite samples were obtained using an invia Laser-Raman spectrometer (Renishaw-invia, England) with a 514 nm radiation. The electromagnetic parameters were measured in a HP8753D vector network analyzer at frequency range of 2–18 GHz. The samples were pressed to be toroidal samples with the height about 3 mm according to the mass ratio 3:1 of paraffin and composite powders.
3 Results and discussion
The XRD patterns of the CoFe2O4/Y3Fe5O12 nanocomposite and the graphene/CoFe2O4/Y3Fe5O12 nanocomposite are shown in Fig. 1. The results suggest that the characteristic peaks for the two phases of Y3Fe5O12 and CoFe2O4 can be found in all samples and no any other phase can be detected. The XRD patterns are consistent with Y3Fe5O12 phase (JCPDS 21-1450) and CoFe2O4 phase (JCPDS 22-1086). The diffraction peaks can be perfectly indexed to the cubic structure of Y3Fe5O12 and the cubic spinel structure of CoFe2O4. It shows that the introduction of graphene will not affect the crystalline structure during the reaction. Therefore, it can be concluded that the graphene/CoFe2O4/Y3Fe5O12 nanocomposite has been obtained during the reaction process, and the two phase of Y3Fe5O12 and CoFe2O4 can be coexisted.
Raman spectroscopy is also one of the most sensitive and informative techniques to characterize disorder in sp2 carbon materials. Figure 2 presents the Raman spectrum of graphite oxide and graphene/CoFe2O4/Y3Fe5O12 nanocomposite. The variation of the relative intensities of G (the E 2g mode of sp2 carbon atoms) and D (the symmetry A 1g mode) bands in the Raman spectra of the graphene during the reduction usually reveals the change of the electronic conjugation state [13,14,15,16]. As depicted in the Fig. 2, the intensity ratio of D to G band (ID/IG) of graphene is 1.05 which is higher than of well-crystallized graphite oxide (0.93). This agrees well with the Raman spectrum of the graphene reduces by hydrazine that is reported by Stankovich et al. [13], indicating the reduction do take place.
Figure 3 show the SEM micrograph of the CoFe2O4/Y3Fe5O12 nanocomposite and graphene/CoFe2O4/Y3Fe5O12 nanocomposite. Figure 3a shows the Y3Fe5O12 and CoFe2O4 phases are well distributed. For graphene/CoFe2O4/Y3Fe5O12 in Fig. 3b, it can be observed that a continuous overlayer of conducting graphene can be formed on the ferrite particle surface. Figure 4 shows the EDS spectrum and the corresponding mapping result of the representative graphene/CoFe2O4/Y3Fe5O12 nanocomposite. It can be found that the whole area of the SEM picture (Fig. 4 b) contains O, Fe, Y, Co and C five elements. The atomic ratio of Co to Y is 0.77, which is approximately equal to the nominal value of 0.78. The mass fraction of Y and Fe in the sample reaches 11.6 and 37.4%, respectively, while it is 7% for the element C. As shown in Fig. 4c, the O, Fe, Y, Co elements are well distributed in the picture, but the C element is distributed in the local area. In this area, the powder is surrounded by the graphene, so the C element is more concentrated than other area.
The overall XPS spectra of graphene/CoFe2O4/Y3Fe5O12 nanocomposite is shown in Fig. 5a. It can be clearly observed that five peaks corresponding to Y 3d, O 1 s, Co 2p, Fe 2p, and C 1 s appear in the sample. The reduction of graphene oxide is also characterized using XPS spectra and Raman spectra. Figure 5b shows the C 1s XPSspectra of graphene/CoFe2O4/Y3Fe5O12 nanocomposite. The peaks 1, 2, and 3 correspond to C=C/C–C in aromatic rings, C–O (epoxy and alkoxy), and C=O, groups, respectively [15]. After the reduction of graphene, the intensities of all C 1 s peaks of the carbons binding to oxygen, especially the peak of C–O (epoxy and alkoxy), decreases dramatically, revealing that most oxygen containing functional groups are removed after reduction.
Figure 6 shows frequency dependence of the complex permittivity, complex permeability and loss tangent of dielectric/magnetic of the samples between 2 and 18 GHz. As we all known, the ε′ and µ′ values stand for storage ability of electromagnetic energy while the ε″ and µ″ values stand for the dissipation of energy. It can be observed from Fig. 6a, b that ε′ and ε″ values of graphene/CoFe2O4/Y3Fe5O12 nanocomposite increase while the µ′ and µ″ values decrease after the introduction of graphene, which is due to the fact that the addition of graphene enlarges the interface of graphene/CoFe2O4/Y3Fe5O12 nanocomposite and makes the dipole and interfacial polarizability of the nanocomposite enhanced in the electromagnetic field, which results in the larger dielectric loss and smaller magnetic loss [17].
In order to investigate microwave absorption properties, the reflection loss (RL) of CoFe2O4/Y3Fe5O12 and graphene/CoFe2O4/Y3Fe5O12 nanocomposite are calculated by the following equations:
where Z in is the input impedance of the absorber, c is the velocity of electromagnetic wave in vacuum, f is the frequency and d is the layer thickness, ε r and µ r are the complex relative permittivity and permeability, respectively.
The calculated reflection loss curves of the samples are shown in Fig. 7. It is clearly seen that there is nearly no broad peak with a bandwidth lower than −15 dB for CoFe2O4/Y3Fe5O12 nanocomposite. However, the introduction of graphene can significantly enhance the microwave absorbing abilities. An effective absorption band is obtained at 14–16 GHz and the maximum reflection loss is −36.1 dB at 14.88 GHz. The strong attenuation characteristics of microwave absorbing materials must satisfy a proper matching of the magnetic loss and dielectric loss [18]. CoFe2O4/Y3Fe5O12 nanocomposite can not achieve the matching of the magnetic loss and dielectric loss. Compared with this, the graphene/CoFe2O4/Y3Fe5O12 nanocomposite possess more proper matching of the magnetic loss and dielectric loss and larger microwave absorbing ability is obtained consequently. The addition of graphene can well balance the magnetic loss and the dielectric loss, and reduces the magnetic-coupling effect between grains, while increase the effective surface anisotropy of the grains [19]. Above these reasons make the graphene/CoFe2O4/Y3Fe5O12 nanocomposite have enhanced microwave absorption properties, becoming the candidate for the good microwave absorbing materials.
The microwave absorption performance can be mainly related to the specimen thickness effect [20]. The calculated microwave reflection loss in 2–18 GHz for graphene/CoFe2O4/Y3Fe5O12 nanocomposite with different specimen thicknesses is shown in Fig. 8. It is found that the peak values shifts to a lower frequency with specimen thickness increase. The reflection loss values exceeding −30 dB can be obtained by tuning the specimen thickness between 3 and 2 mm. This affirms that the thickness of the sample also plays a major role in the microwave absorption performance of the sample.
4 Conclusions
The graphene/CoFe2O4/Y3Fe5O12 nanocomposite were successfully synthesized by a deoxidation technique. XRD and SEM studies have established formation of the graphene/CoFe2O4/Y3Fe5O12 nanocomposite. The Raman and XPS measurements shows the reduction of the graphene, which has good electrical conductivity properties. Our results indicate that the graphene/CoFe2O4/Y3Fe5O12 nanocomposite exhibits good absorption performances and the maximum reflection loss of the nanocomposite can reach to −36.1 dB. Therefore, the prepared graphene/CoFe2O4/Y3Fe5O12 nanocomposite becomes potential candidate in microwave absorping field.
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Acknowledgements
This research was supported by the National Natural Science Foundation of China (51372144) and the Key Program of Innovative Research Team of Shaanxi Province (2014KCT-06).
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Wang, Y., Pu, Y., Shi, Y. et al. Excellent microwave absorption property of the CoFe2O4/Y3Fe5O12 ferrites based on graphene. J Mater Sci: Mater Electron 28, 12866–12872 (2017). https://doi.org/10.1007/s10854-017-7116-y
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DOI: https://doi.org/10.1007/s10854-017-7116-y