Ultrathin SmCo5 nanoflakes with high-coercivity prepared by solid particle (NaCl) and surfactant co-assisted ball milling

The ultrathin SmCo5 nanoflakes with average thickness smaller than 50 nm are prepared by a novel method of solid particle (NaCl) and surfactant co-assisted ball milling. The as-prepared nanoflakes exhibit a narrower thickness distribution of 10–50 nm and high coercivity of 23 kOe. The possible formation mechanism of nanoflakes are proposed. Temperature dependence of demagnetization curves indicate that the magnetization reversal may be controlled by both nucleation and pinning. The results of X-ray powder diffraction and magnetic measurement for aligned SmCo5 nanoflakes resin composite indicate that the nanoflakes have a high texture degree. The ultrathin thickness and high coercivity are beneficial for preparing the high performance soft/hard coupling magnets and nanocomposite magnets.

Ultrathin SmCo 5 nanoflakes with high-coercivity prepared by solid particle (NaCl) and surfactant co-assisted ball milling

Wen-Liang Zuo, Xin Zhao, Tong-Yun Zhao, Feng-Xia Hu, Ji-Rong Sun & Bao-Gen Shen
The ultrathin SmCo 5 nanoflakes with average thickness smaller than 50 nm are prepared by a novel method of solid particle (NaCl) and surfactant co-assisted ball milling. The as-prepared nanoflakes exhibit a narrower thickness distribution of 10-50 nm and high coercivity of 23 kOe. The possible formation mechanism of nanoflakes are proposed. Temperature dependence of demagnetization curves indicate that the magnetization reversal may be controlled by both nucleation and pinning. The results of X-ray powder diffraction and magnetic measurement for aligned SmCo 5 nanoflakes resin composite indicate that the nanoflakes have a high texture degree. The ultrathin thickness and high coercivity are beneficial for preparing the high performance soft/hard coupling magnets and nanocomposite magnets.
Nanostructured Co-based rare-earth permanent materials with high coercivity and strong texture have drawn much attention due to their high temperature application and which can be used for preparing the high-performance soft/hard exchange coupled permanent magnet and high-density data storage media 1-4 . Furthermore, the particle sizes are the smaller the better as long as they are larger than the supperparamagnetic transition size for soft/hard coupling magnet or nanocomposite magnet 5 . However, synthesis of high-quality rare-earth compounds with small size turns out to be a non-trivial task due to the great chemical instability 5,6 . Wet-chemical methods are commonly used for preparing the nanoparticles with controlled size. However, until now it is still limited success in obtaining high coercivity and high purity samples 4,5 . Physical method of cluster-deposition is also used to produce the textured rare-earth compounds nanomagnets 7 . Nevertheless, not only the equipment is expensive, but also the yield is low. Surfactant-assisted ball milling (SABM) is also used for preparing the rare-earth based hard magnetic nanomaterials 6,8 . Unfortunately, most of the experiment results exhibit the large thickness and wide size distribution [8][9][10] , although the further centrifugal separation can be used obtain smaller size 6 , both the low output and low coercivity limit its development. In recent work, we prepared the SmCo 5 nanoflakes with ultrahigh coercivity of 26.2 kOe using a multistep SABM 11 . However, the thickness of that nanoflakes is still about 50-200 nm, the further decrease in thickness can cause the speedy decrease of coercivity. In this articles, a novel method of the solid particle (NaCl) and surfactant co-assisted ball milling (SPSABM) are used for preparing the ultrathin rare-earth permanent magnetic (SmCo 5 ) nanoflakes with narrow size distribution and high coercivity. The results indicate that it is a fine method for decreasing the thickness of nanoflakes but still keep the high coercivity. Figure 1 shows the evolution mechanism of SmCo 5 nanoflakes with the SPSABM time from 0 to 20 h. The start powders of SmCo 5 compound and NaCl are shown in Fig. 1(a). It can be seen that the SmCo 5 compound shows irregular shape with the size of 50-400 μ m, while the NaCl exhibits regular cube with size about 150 μ m. With the increase of milling time reaches 8 h (See Fig. 1(b)), the solid particle (NaCl) and the milling materials (SmCo 5 ) are grated into smaller size. The elemental analysis of energy dispersive spectroscopy (EDS) is shown in Table 1. It is interested that NaCl particles become smaller than SmCo 5 flakes. In this conditions, the NaCl nanoparticles will easily fill in the interspaces of SmCo 5 flakes and milling balls, the according schematic is shown in the right of Fig. 1(b), where square, rectangle and semicircle represent the solid particle (NaCl), nanoflakes (SmCo 5 ) and milling ball, respectively. It is obvious that the NaCl nanoparticles will be used as a pivot and the intensity of pressure in the pivot of nanoflakes will dramatically increase, which promotes the nanoflakes further smashing but has little effect on other part of the nanoflakes, it also means the breaking effect may be only at the point rather than the whole plane (smaller contact area), which can decrease the percentage of crystal structure defects of the nanoflakes than the traditional ball milling at the same condition. It should be noted that the schematic only shows three types of possible situation, and realistic situation may be more complex. When the milling time reaches to 20 h, the ball milling product is collected in the test-tube and let it stand for 4 h, the picture is shown in Fig. 1(c). It can be seen that the milling product exhibits obvious layering. In the bottom of cylinder (black regions) is mainly SmCo 5 nanoflake, the middle (Grey white regions) is mainly NaCl, and the top (black regions) is the liquid (include Heptane, Oleylamine, oleic acid, and very small amount of SmCo 5 and NaCl nanoparticles). The spontaneous layering is very important for further purification and could be due to the density of NaCl smaller than that of SmCo 5 . The bottom slurry of test-tube is washed three times using Heptane, then collected for measurement. The SEM image of the as-milled nanoflakes is shown in Fig. 2, the top left and top right are the enlarged image and histogram of selected area, respectively. It can be seen that the thickness of nanoflakes are mainly distributed in the range of 10-50 nm, which indicates that the SPSABM are advantageous for obtaining the narrower size distribution and smaller thickness than the traditional SABM [9][10][11][12][13] . Both the narrower size distribution and smaller thickness are favorable for preparing the high performance soft/hard coupling magnets and nanocomposite magnets. Furthermore, there is no trace of NaCl in the nanoflakes, which will be demonstrated by XRD (See Fig. 3(a)) and is important for actual production and application. Moreover, the nanoflakes show smaller diameter (1-2 μ m) compared with the usual SABM with high energy [8][9][10] , which is beneficial for further increasing the coercivity due to decreasing the effect of local demagnetization fields. As usual, the nanoflakes also form "kebab-like" morphology due to the c-axis texture and magnetostatic interaction, which implies that the easy magnetization direction of as-milled SmCo 5 nanoflakes is perpendicular to the surface of the flakes. The XRD pattern of as-milled SmCo 5 nanoflakes with randomly oriented is shown in Fig. 3(a). It can be seen that the as-milled powder mainly exhibits the hexagonal SmCo 5 phase (JCPDS PDF#65-4844) and no the trace of NaCl (JCPDS PDF#05-0628). It agrees with the result of SEM (See Fig. 2) and indicates that the NaCl and SmCo 5 can be easily separated. In addition, the XRD pattern of aligned sample is also shown in Fig. 3(b). It can be seen that the diffraction intensity of (00l) crystalline planes remarkably enhances while the other peaks almost disappear, suggesting that the aligned sample possesses a strong (00l) alignment (the easy magnetization directions along the c-axis). The normalized c-axis alignment degree is 99% for the aligned SoCo 5 nanoflakes resin composite according to the papers 14-16 , the lattice parameters (PDF#65-4844) and intensity of diffraction peaks are obtained from Fig. 3. Which indicates that the ultrathin SmCo 5 nanoflakes maintain a high texture degree. Figure 4(a) shows the hysteresis loops of aligned SmCo 5 nanoflakes resin composite. Firstly, the obviously anisotropy magnetic behaviors are observed, which indicates that the nanoflakes have a large magnetic anisotropy. Secondly, a high coercivity of 23 kOe is obtained along the easy axies, which is about 40% higher than the traditional SABM 8 , and gives the nanoflakes great potential application. In addition, we also calculate the average misalignment angle, ϕ = arctan[2M r (⊥ )/2M r (||)] 17,18 , where M r (⊥ ) and M r (||) are the remanence of perpendicular and parallel direction of the easy axis, respectively. The misalignment angle ϕ = 19.6°, which indicates that the nanoflakes with SPSABM have a high texture degree compared with the experiment results of SABM in the magnetic field 17,19 . In here, it should be known that the calculated results of texture degree form XRD and VSM are consistent although the values are seemingly different. Which are mainly due to two different evaluation system, the data from XRD shows the alignment of crystal texture, while the data from M-H loops reflect the alignment of magnetization (or the magnetic domain). As the fact that there are slight nanopaticles or nanoflakes with very small size in the grain boundaries 8,19 , that incline to random orientation due to the amorphous and superparamagnetic, and they couldn't be checked by XRD but is very sensitive to reverse magnetization process (namely, the domain structure), especially for the hard magnetic materials. In addition, the effect of amorphous and superparamagnetic can also be reflected in the demagnetization curves. The approximately linear decrease of magnetization in the second quadrant indicates that there really exist some low coercivity materials together with the high coercivity nanoflakes, which most possibly are the amorphous SmCo 5 materials according to the ball milling method and other paper 8,13 . However, the phenomenon is more inconspicuous than that of the high energy SABM 8,19 , which indicates the SPSABM could be beneficial for decrease the defect and obtaining the ultrathin SmCo 5 nanoflakes with high coercivity. In order to study the mechanism of high coercivity, the temperature dependence of demagnetization curves are shown in Fig. 4(b). According to the micro magnetic model, the coercivity can be generally expressed as 20,21 : H c = α K α ϕ 2K 1 /μ 0 M s − N eff M s , where K 1 , N eff , and M s are the first-order anisotropy constant, the effective local demagnetization factor and the saturation magnetization, respectively. The coefficient α K represents the effect of the sample microstructure, especially for the inhomogeneous intrinsic material parameters, and α ϕ describes the information of the easy axis misaligned. These parameters can be determined by linear Fig. 4(b)). The temperature dependent values of K 1 and M s are from the SmCo 5 single crystal 22 . The obtained α K α ϕ and N eff are 0.125 and 2.19, respectively. The value of 0.125 is mainly attributed to the microstructure parameter α K due to the small misalignment angle for the aligned samples, and this value is similar (and slightly smaller) to the multistep ball milled SmCo 5 nanoflakes, which could be attributed to the slightly smaller misalignment angle 11 . And this also indicates that the ultrathin SmCo 5 nanoflakes have a similar microstructure compared with the multistep ball milled SmCo 5 nanoflakes. In addition, the α K α ϕ value of 0.125 indicates that the magnetization reversal may be controlled by both nucleation and pinning (α K < 0.3) 20,23 . The value of N eff is larger than 1 and slightly smaller than that of the multistep ball milled SmCo 5 nanoflakes 11 , which could be due to the smaller thickness 24 . Meanwhile which also indicates that the smaller stray field is existed in the ultrathin SmCo 5 nanoflakes resin composite compared with that of multistep ball milled results due to the larger local demagnetization effect (larger aspect-ratio) 19,20,23 .
The ultrathin SmCo 5 nanoflakes are prepared by a novel method of solid particle (NaCl) and surfactant co-assisted ball milling. The as-prepared nanoflakes exhibit a narrower thickness distribution of 10-50 nm and high coercivity of 23 kOe. The result of XRD and VSM for aligned SmCo 5 nanoflakes resin composite indicates that the ultrathin nanoflakes have a high texture degree. The small thickness, narrow size distribution and large coercivity are beneficial for preparing the high performance soft/hard coupling magnets and nanocomposite magnets. The low cost of equipment and high output further give the nanoflakes greatly potential practical application.

Methods
SmCo 5 ingots were purchased from Taiyuan Tianhe Hi Tech Co Ltd, and were annealed at 1173 K for a week under vacuum, then ground down to less than 400 μ m as the starting powders. The SPSABM experiment was performed using a GN-2 BM equipment with the speed was about 250 rpm. Oleylamine (80-90%) and oleic acid (99%) were used as surfactants, the total amount was 20% to the weight of the starting powders (Oleylamine and oleic acid was 1:1). NaCl was used as the solid particle, the size was about 150 μ m, and the weight was 3:1 compared with the starting powders. Heptane (99%) was used as the carrier liquid. The aligned SmCo 5 nanoflakes resin composite was prepared by mixing the as-milled nanoflakes with epoxy resin, and placing them into a 20 kOe magnetic field until the epoxy resin solidifies. The phase structure was examined by the X-ray powder diffraction (XRD) with Cu Kα radiation at room temperature. Morphology was analyzed by scanning electron microscope (SEM). Magnetic properties were measured by a SQUID VSM with the maximum field of 70 kOe.