Abstract
Developing optically transparent magnets at room temperature is an important challenge. They would bring many innovations to various industries, not only for electronic and magnetic devices but also for optical applications. Here we introduce FeCo-(Al-fluoride) nanogranular films exhibiting ferromagnetic properties with high optical transparency in the visible light region. These films have a nanocomposite structure, in which nanometer-sized FeCo ferromagnetic granules are dispersed in an Al-fluoride crystallized matrix. The optical transmittance of these films is controlled by changing the magnetization. This is a new type of magneto-optical effect and is explained by spin-dependent charge oscillation between ferromagnetic granules due to quantum-mechanical tunneling.
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Introduction
Magnets with transparency to light are very promising for new applications. Various transparent magnetic materials have been proposed (e.g., magnetic semiconductors doped with ferromagnetic elements such as Co1,2,3 and nanocrystalline iron oxides such as magnetite (Fe3O4)4 and hematite (Fe2O3)5,6). However, materials with large magnetization and high optical transparency at room temperature have not yet been realized. In semiconductors, either the magnetization is too small at room temperature to be useful for applications or the magnetic transition temperatures are too low. If iron oxides have strong magnetization, the optical transparency is low (Fe3O4); and if they have high optical transparency, the magnetization is very weak (Fe2O3). On the other hand, magnetorefractive effect in nanogranular films and multilayers with giant magnetoresistance (GMR) has been reported7,8,9,10,11. Magnetorefractive effect is a magneto-optical effect due to GMR.
In this study, we present FeCo-(Al-fluoride) nanogranular films exhibiting ferromagnetic properties with high optical transparency in the visible light region. Optical transmittance is controlled by changing the magnetization. This is a new magneto-optical effect that is explained by the tunneling magneto-dielectric (TMD) effect12,13.
Nanogranular films consisting of nanometer-sized magnetic metal granules and a ceramic insulating matrix exhibit various functional properties depending on the composition ratio of the two elements, granules to matrix14,15. Because dielectric and optical properties are intimately correlated16, there is significant interest in the optical properties of nanogranular films with the TMD effect. In addition, these films have significant practical advantages (e.g., they are easily fabricated and are thermally stable17,18 and have been applied in magnetic sensors19,20).
Results
Optical and magnetic properties of FeCo-(Al-fluoride) nanogranular films
Figure 1a is a photograph of a Fe9Co5Al19F67 film deposited on a glass substrate (Corning Eagle 2000) heated to 660 °C. The film is about 1 μm thick. Red, blue and yellow letters behind the thin film are seen clearly. Figure 1b shows the dependence of the transmittance on the light wavelength in the Fe9Co5Al19F67 film presented in Fig. 1a. This film has substantial optical transmittance even for short wavelengths less than 400 nm, which is the limit that can be measured in this experiment and exhibits a high transmittance of 90% to light of wavelength 1500 nm, which is in the band for optical communications. The magnetization curve of the Fe9Co5Al19F67 film is presented in Fig. 1c. The film exhibits hysteresis and the magnetization is 18 kA/m, confirming that the film has both good optical transmittance and ferromagnetic properties.
Figure 2a shows a high-resolution transmission electron microscope image obtained from the Fe9Co5Al19F67 film depicted in Fig. 1. This film consists of FeCo magnetic alloy of nanometer-sized granules dispersed in an Al-fluoride matrix. This micrograph has many dark circles with diameters ranging from 10 to 15 nm. In addition, a bright section covers the whole area. The dark circles are FeCo alloy granules and the bright section with a lattice pattern indicates the Al-fluoride matrix with AlF3 crystal structure.
Fluoride crystals (e.q., MgF2 and BaF2) have good transmittance and are widely used as optical materials. AlF3 crystals also exhibit good transmittance from the short-wavelength region (200 nm) to near-infrared (2000 nm). On the other hand, FeCo is a ferromagnetic alloy with the largest known magnetization21. FeCo alloy granules with diameters exceeding 10 nm exhibit ferromagnetism because the granules are larger than the superparamagnetic critical diameter22 at room temperature. However, since the diameter of the granules is very small compared to the light wavelength, light can pass through the film (to be discussed later). If the density of the FeCo granules in the film increases, transmittance decreases (Fig. 2b). This behavior can be explained simply since the FeCo granules are of the origin of the ferromagnetic properties while the Al-fluoride matrix allows optical transparency.
Figure 3a depicts the change in the transmittance (ΔT/T0) of light with wavelength of a 1500 nm, Fig. 3b presents the magnetization curve of the Fe13Co10Al22F55 film. Transmittance decreases with an increase of magnetic field. The hysteresis of the transmittance is caused by the magnetization, as seen in Fig. 3. Here, ΔT = TM−T0, where TM is the transmittance with the magnetization M and T0 is that with zero magnetization. Table 1 lists ΔT/T0, the magnetization and the transmittance in Fe9Co5Al19F67 (Fe + Co = 14 at.%) and Fe13Co10Al22F55 (Fe + Co = 23 at.%) films. ΔT/T0 is observed in both films. It is noteworthy that optical transmittance changes with the magnetic field (ΔT/T0 = 0.03% and 0.05%). As indicated in Fig. 3a, the magnetic fields at which two of the maxima in the transmittance appear are consistent with the coercivity. This result clearly confirms that the change in the transmittance corresponds to magnetization. The DC resistivity of the films shown in Fig. 3 and Table 1 is larger than 1011 μΩ m and the magnetoresistance was not observed. The result in Fig. 3 and Table 1 demonstrate a new magneto-optical effect in transparent nanogranular films.
Mechanism of optical transmission responses in nanogranular films
Optical transmission responses to magnetization in nanogranular films may be explained by the TMD effect. Figure 4 illustrates a nanogranular structure with the image of optical transmittance and a model of a granular pair. The magneto-optical response is due to transition of electric charges between neighboring ferromagnetic granules through an insulating barrier via quantum-mechanical electron tunneling23,24, which depends strongly on the relative orientation of magnetization of the granules. When optical light is incident on the film, electric charge carriers in granules are subject to the oscillating electric field of the light that causes tunneling of the charge carriers back and forth between neighboring granules through the thin insulator barrier (Fig. 4). The oscillation of charging states between granules is spin-dependent and contributes to additional magneto-dielectric and optical responses of nanogranular films24.
Incorporating the TMD constant12 with a broad distribution of dielectric relaxation around the characteristic relaxation time24,25 , where PT is the tunneling spin polarization, m = (M/Ms) is the normalized magnetization and Ms is the saturation magnetization, we have the total magneto-dielectric constant of granular films
where εr(ω) is the effective dielectric constant of the media in the absence of tunneling effect between granules, Δεm(ω) is the tunneling contribution12, Δε is the dielectric strength and β is the Cole-Cole’s exponent (0 < β ≤ 1) representing a measure of the distribution of relaxation time26. In magnetic nanogranular films, β = 0.7 to 0.8 was found in a previous study12.
Using the dielectric constant (1) in the formula of transmission for a normal-incident optical light through a film27, we obtain the magneto-optical transmittance of a granular film as , where Δα0 is the magneto-optical absorption coefficient and d is the film thickness (see Methods for details). In Fig. 3a, we fit the magnetic field dependence of ΔT/T0 using the experiment data of the magnetization curve in Fig. 3b for the optical light of wave-length λ = 1500 nm and frequency ω = 108 s−1, refractive index nr = 3 and film thickness d = 1000 nm. Using the values of PT = 0.5, β = 0.7 (PT and β values are a little different from the previous results12. This is because of the increase of the granule size and the granule size distribution as seen in Fig. 2), Δε = 300 and τ0 = 10−8 s, appropriate for the Fe+Co of 23 at.% granular film12 and Δα0d = (2πd/nrλ)(ωτ0)−βΔεsin(βπ/2) = 2.3×10−3 we find a good agreement between the experiment and theoretical data (Fig. 3a), in particular for the hysteretic behavior of the transmittance reflecting the magnetization process in Fig. 3b. The magnetic fields, at which the transmittance is greatest, coincide with the coercive fields where there is a change of sign in the magnetization curves.
The values of ΔT/T0 can be enhanced if one uses a half-metal with full spin polarization (PF = 1) for ferromagnetic nanogranules; makes the granule density higher, which shortens relaxation time due to the reduced distance between granules; and designs broader size distribution, which makes β smaller. Nanogranular structures can be controlled by changing the film composition, the deposition conditions and the annealing. For instance, when the values of PF = 1 and τ0 = 10−9 s are used, large magneto-optical transmittances of ΔT/T0 (~5% for β = 0.6 and ~10% for β = 0.5 are expected in half-metallic nanogranular films.
Discussion
We have reported that nanogranular FeCo-(Al-fluoride) films are optically transparent ferromagnetic materials. These films have transmittance even for short wavelengths of light (less than 400 nm), exhibit 90% transmittance at a wavelength of 1500 nm and are ferromagnetic with magnetization exceeding 18 kA/m at room temperature. Furthermore, these films have magneto-transmittance response ΔT/T0 of 0.05% at a wavelength of 1500 nm. This new magneto-optical phenomenon is explained by the TMD effect due to the spin-dependent quantum effect in the nanogranular structure. A large value of ΔT/T0 (more than 10%) is expected theoretically in nanogranular films by optimizing material and structural conditions.
Magnetic materials in electric devices are not optically transparent. With the realization of a transparent magnet, more complete display devices will be constructed. For example, speed and fuel meters and a map can be displayed directly on the front glass of a car or an airplane.
Methods
Preparation of thin film samples
Thin films were prepared by a tandem deposition method28 using a conventional RF-sputtering apparatus. Sputter deposition was performed on a 50 × 50 mm glass (Corning Eagle 2000) substrate at 600 to 700 °C in argon atmosphere with 1.3 Pa pressure during deposition, using a 76 mm-diameter Fe60Co40 alloy disk target and an AlF3 powder target compacted in the form of a 76 mm-diameter disk.
Composition and structural analysis
The composition ratio of Fe-Co (granule) and Al-F (matrix) was controlled by changing the RF power applied to each target. The chemical composition of Fe, Co, Al and F in the thin films was analyzed using wavelength dispersion spectroscopy (WDS). For structural analysis, transmission electron microscopy (TEM) was performed on several selected thin films.
Measurements of optical and magnetic properties
Optical transmittance was measured using Fourier transform infrared spectroscopy (FTIR) with a measurement waveband of 400 to 2000 nm. Change in the transmittance was measured using an optical spectrometer with a measurement waveband of 900 to 2000 nm and a magnetic field of 0 to 480 kA/m. The magnetization curves were measured using a vibrating sample magnetometer (VSM). In the magnetization and magneto-optical measurements, a magnetic field was applied parallel to the films surface. All the measurements reported in this paper were carried out at room temperature.
Derivation of the transmittance
The transmittance of the electromagnetic wave incident normal to the plane of a film with the effective dielectric constant ε (ω) and thickness d is obtained by calculating the Poynting vectors of the incident, reflected and transmitted electromagnetic waves. The resulting transmittance TM is expressed as27
where Ei is the incident electric field, Et is the transmitted electric field, is the complex wave number, = n + iκ is the complex refractive index, α = 4πκd/λ is the absorption coefficient, θ = 2πnd/λ, φ = −tan−1[2κ/(n2 + κ2−1)], λ is the wave length and R0 = [(n−1)2 + κ2]/[(n + 1)2 + κ2].
The interference is weak (Fig. 1b), due to modulation of film thickness and/or refractive index, which allows us to average TM over (θ−φ) from 0 to 2π, yielding25
The effective dielectric constant of granular films may be separated into the two contributions
where εr(ω) is the effective dielectric constant in the absence of the tunneling effect between granules and Δεm(ω) is the tunneling contribution of the form12,
where Δε is dielectric strength; τm is the characteristic relaxation time given by the spin-dependent tunneling rate24,25 where PT is the tunneling spin polarization, M is the magnetization and Ms is the saturation magnetization; and β is an exponent representing a measure of the distribution of relaxation time26 (β ~ 0.7 to 0.8 in the granular films12). In the optical region, the light frequency (~1015 s−1) is much higher than the tunneling rate (~104 s−1 to 109 s−1) depending on the ferromagnetic composition12 (ωτm≫1) so that the tunneling contribution is approximated as Δεm(ω) ≈ Δεe−iβπ/2(ωτm)−β.
In the optical region (ωτm≫1), the refractive index can be expanded with respect to the tunneling contribution Δεm(ω) as
where
The real and imaginary parts of the complex refractive index are written as
where
in the highly transparent region (kr/nr)2≪1.
It follows from Eqs (3), (9) and (10) that the dominant contribution to the magneto-optical effect arises from the magneto-optical part Δαm of the absorption coefficient α = αr + Δαm, where αr = 4πκr/λ and Δαm = 4πΔκm/λ, yielding the transmittance
as a function of applied magnetic field H through the magnetization curve M(H). Therefore, the magneto-transmittance effect of a granular film is obtained as
where Δα0 = (2π/nrλ)(ωτ)−βΔεsin(βπ/2) and m = M(H)/Ms. Equation (12) is used to analyze the experimental results of the magneto-optical transmittance ratio ΔT/T0 versus applied magnetic field H in the Fe13Co10Al22F55 (Fe+Co = 23 at.%) film, as illustrated in Fig. 4.
Additional Information
How to cite this article: Kobayashi, N. et al. Optically Transparent Ferromagnetic Nanogranular Films with Tunable Transmittance. Sci. Rep. 6, 34227; doi: 10.1038/srep34227 (2016).
References
Ogale, S. B. et al. High temperature ferromagnetism with a giant moment in transparent Co-doped SnO2-δ . Phys. Rev. Lett. 91(077205), 1–4 (2003).
Fukumura, T. et al. Role of change carriers for ferromagnetism in cobalt-doped rutile TiO2 . New Journal of physics 10, 055018 (2008).
Janisch, R., Gopal, P. & Spaldin, N. A. Transition metal-doped TiO2 and ZnO-present status on the field. J. Phys. Condens. Matter. 17, 657–689 (2005).
Baghaie Yazdi, M. et al. Transparent magnetic oxide thin films of Fe3O4 on glass. Thin Solid Films 519, 2531–2533 (2011).
Ziolo, R. F. et al. Matrix-Mediated Synthesisi of Nanocrystalline γ-Fe2O3: A new optically transparent magnetic material. Science 257, 219–222 (1992).
Ohkoshi, S. et al. Nanometer-size hard magnetic ferrite exhibiting high otical-transparency and nonlinear optical-magnetoelectric effect. Nat.Commun. 5, 14414 (2015).
Granovsky, A. B. et al. Magnetorefractive effect in nanocomposites: dependence on the angle of incidence and on light polarization, Physics of the Solid State 46, 498–501 (2004).
Lobov, I. D. et al. Magnetorefractive Effect and Giant Magnetoresistance in Fe(tx)/Cr Superlattices. Physics of the Solid State. V.51, 2480–2485 (2009).
Granovskii, A. B. et al. Magnetorefractive effect in nanostructures, manganites and magnetophotonic crystals based on these materials. Journal of Communications Technology and Electronics 52, 1065–1071 (2007).
Vopsaroiu, M., Bozec, D., Matthew, J. A. D. & Thompson, S. M. Contactless magnetoresistance studies of Co/Cu multilayers using the infrared magnetorefractive effect. Physical Review B70, 214423 (2004).
Akbashev, A. R., Telegin, A. V., Kaul, A. R. & Sukhorukov, Y. P. Granular and layed ferroelectric-ferromagnetic nanocomposites as promising materials with high magnetotransmission. J. Magn. Magn. Mater. 384, 75–78 (2015).
Kobayashi, N., Masumoto, H., Takahashi, S. & Maekawa, S. Giant dielectric and magnetoelectric responses in insulating nanogranular films at room temperature. Nat.Commun. 5, 5417 (2014).
Kobayashi, N., Iwasa, T., Ishida, K. & Masumoto, H. Dielectric properties and magnetoelectric effects in FeCo-MgF insulating nanogranular film. J. Appl. Phys. 117, 014101 (2015).
Fujimori, H., Ohnuma, S., Kobayashi, N. & Masumoto, T. Spintronics in metal-insulator nanogranular magnetic thin films. J. Magn. Magn. Mater. 304, 32–35 (2006).
Ohnuma, S., Kobayashi, N., Fujimori, H. & Masumoto, T. Metal-insulator type nano-granular magnetic thin films. J. Phys.: Conf. Series 191, 012020 (2009).
Kuzmany, H. Solid State Spectroscopy. 2nd ed. (Springer, Berlin, 2009).
Kobayashi, N., Ohnuma, S., Masumoto, T. & Fujimori, H. Effects of substrate temperature and heat treatment on GMR properties of Co-RE-O nano-granular films. Materials Transactions, JIM 39, 679–683 (1998).
Kobayashi, N., Ohnuma, S., Fujimori, H. & Masumoto, T. TMR and thermal stability improvement FeCo-AlF nano-granular thin films. J. Japan. Inst. Metals 76, 375–379 (2012).
Kobayashi, N. et al. Enhancement of low-field magnetoresistive response of tunnel-type magnetoresistance in metal-nonmetal granular thin films. J. Magn. Magn. Mater. 188, 30–34 (1998).
Kobayashi, N., Ohnuma, S., Masumoto, T. & Fujimori, H. (Fe-Co)-(Mg-fluoride) insulating nanogranular system with enhanced tunnel-type magnetoresistance. J. Appl. Phys. 90, 4159–4162 (2001).
Bozorth, R. M. Ferromagnetizn Van Nostrand Co. Inc. (1951).
Yakushiji, K. et al. Composition dependence of particle size distribution and giant magnetoresistance in Co-Al-O granular films. J. Magn. Magn. Mater. 212, 75–81 (2000).
Maekawa, S. & Gäfvert, U. Electron tunneling between ferromagnetic films. IEEE Trans. Mag. 18, 707–708 (1982).
Inoue, J. & Maekawa, S. Theory of tunneling magnetoresistance in granular magnetic films. Phys. Rev. B 53, R11927–R11929 (1996).
Mitani, S., Fujimori, H. & Ohnuma, S. Spin-dependent tunneling phenomena in insulating granular systems. J. Magn. Magn. Mater. 165, 141–148 (1997).
Cole, K. S. & Cole, R. H. Dispersion and absorption in dielectrics. J. Chem. Phys. 9, 341–351 (1941).
Kuzmany, H. Solid State Spectroscopy. 2nd ed. (Springer, Berlin, 2009).
Kobayashi, N., Ohnuma, S., Masumoto, T. & Fujimori, H. Tunnel-type magnetoresistance in metal-nonmetal granular films prepared by tandem deposition method. J. Magn. Soc. Jpn. 23, 76–78 (1999).
Acknowledgements
The authors are grateful to T. Masumoto and K. I. Arai for valuable discussions. They are indebted to K. Ishida for the sample preparation and to T. Iwasa for the measurement of optical transmittance. This work was supported by Engineering and Grant-in-Aids for Scientific Research (Grant No. 26289253) from the JSPS and Nippon Sheet Glass Foundation for Materials Science.
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The experiments were carried out by N.K. The data was discussed by N.K. and H.M. The theoretical model was developed by S.T. and S.M. All authors contributed to the writing and editing of the paper.
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Kobayashi, N., Masumoto, H., Takahashi, S. et al. Optically Transparent Ferromagnetic Nanogranular Films with Tunable Transmittance. Sci Rep 6, 34227 (2016). https://doi.org/10.1038/srep34227
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DOI: https://doi.org/10.1038/srep34227
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