Nowadays, tungstate materials, BaSO₄, have attracted much attention in view of its luminescent behavior and structural properties [1] [2] . As compared to other materials, the narrow line width of its stimulated Raman scattering (SRS)-active mode in BaSO₄ crystal (1.6 cm⁻¹) leads to high peak intensity (63%). In parti- cular, Raman gain has been measured to be 8.5 cm/GW at 1.06 μm wavelength [2] . Furthermore, the material is not hydroscopic and transparent in visible and near-infrared spectral range. It is a promising material for crystalline nano- and picoseconds Raman lasers. A number of methods, including hydrothermal method, flux method and solid-state reaction [3] - [8] , have been developed to generate tungstate materials. However, tough reaction conditions, such as high- reaction temperature, long-reaction time or complex equipment, were applied in most this approaches [9] . Thus, seeking efficient but low-cost techniques for synthesizing BaSO₄ is required for the development of electro-optical materials.

It is well known that different surfactants can form micelles with variable morphologies. This can be utilized for the modification of crystal growth [10] [11] [12] . For example, Zhang et al. [12] reported that the penniform super structures of BaWO₄ nanowires have been successfully synthesized in reverse micelles by using a block copolymer as the directing agent. The effects of the mixing ratio between the anionic and cationic surfactants on the crystal growth of BaWO₄ nanowires have been further studied. As proposed, the different morphologies and sizes of BaWO₄ crystals could be synthesized by the employ- ment of super-molecule templates composed of biomembrane and organic reagents at room temperature [13] . However, the BaWO₄ nanoparticles with high crystalline and various regular shapes are required in order to enhance physiccal properties. It has thus been indicated that the BaWO₄ microparticles with well crystallinity should be obtained through simple method. Whereas, the composition of the microemulsion influences the structures of the surfactant aggregation as well as the size and shape of the final nanocrystals [14] [15] .

Therefore, the present study was conceived to develop BaWO₄ nanoparticles in a water-in-oil (W/O) microemulsion system composed of 1,4-dioxane and water. The phases, morphologies, and luminescent properties have been investigated.

BaCl₂∙2H₂O and Na₂WO₄∙2H₂O with analytical grade purity were used as, and all other chemical reagents were analytical grade. BaWO₄ nanoparticles were obtained from BaCl₂ and Na₂WO₄ microemulsion system according to the following reaction:

Firstly, 4-dioxane and distilled water were mixed together to prepare a microemulsion system with different volume ratios. Secondly, BaCl₂∙2H₂O (0.061 g) and Na₂WO₄∙2H₂O (0.0821 g) were dissolved in an aliquot of 10 mL of microemulsion system, respectively. The mixture containing Na₂WO₄ were then added dropwise into the flask containing BaCl₂ at 35˚C and 150 rpm. After mixing for 10 min, the sample was centrifuged at 4024 ×g for 5 min and the white precipitates were collected. Finally, the white precipitates were rinsed three times with distilled water and dried at 80˚C for 6 h.

The X-ray diffraction (XRD) patterns were recorded using a Janpan Ridaku D/Max-γA X-ray diffractometer. The particles size and morphology were cha- racterized by scanning electron microscopy (SEM, JEM-200CX) and transmission electron microscopy (TEM, JEOL-2010). Raman spectra were measured at the 514.5 nm line of an Ar laser (Labram HR800).

The obtained BaWO₄ particle in water-in-oil (W/O) microemulsion system was characterized by XRD, and the typical XRD pattern was shown in Figure 1, in which all the peaks could be indexed to the pure BaWO₄ particle with a tetragonal unit cell (a = b = 0.5626 nm, c = 1.2744 nm). This can be indexed to the JCPDS Card No. 82,457 [12] . No other peaks were detected in the pattern, indicating the high purity of the BaWO₄ particle.

The typical TEM images of products synthesized with different ratio of 4- dioxane and distilled water were displayed in Figure 2. Figure 2(a) showed that BaWO₄ particles with large side length were developed without the addition of 4-dioxane.Whereas, as can be seen from Figure 2(b) and Figure 2(c), with an increase of the ratio of 4-dioxane and distilled water from 3:7 to 5:5, the diame- ter of produced rods significantly reduced from 500 nm to 30 nm. Finally, as indicated from Figure 2(d), when the ratio value reached 6:4, it totally transformed from rods to fine spherical particles. These images implied that the concentration of 4-dioxane played a crucial role in the formation of BaWO₄ nanorods. Generally, the formation of BaWO₄ crystal basically consists of a nucleation step followed by particle growth stages: In the initial stage, some of nuclei were formed. However, in the particle growth stages, the development of the crystallite is controlled by 4-dioxane. 4-dioxane is also considered as a stabilizer preventing the aggregation during the formation of nanocrystals. Thus, no special morphologies would form in the single aqueous system in the absence of 4-dioxane because no formation of templates for the preparation of BaWO₄ nanorods. It is well known that different concentrations of surfactants can form micelles with varied morphologies [15] , which could be utilized for the modifi- cation of crystal growth. Nevertheless, higher concentration of 4-dioxane on BaWO₄ crystals resulted in an isotropic growth mode and nearly equiaxial particles, which unfavored the formation of BaWO₄ nanorods. Similar results have also been reported by other groups [14] [16] [17] . Additionally, the TEM and

SEM image of BaWO₄ nanorods prepared in the solvents with the ration value of 4:6, was showed in Figure 3. The side length was approximately 600 nm, and the diameter was about 50 nm.

The Raman spectra of the produced BaWO₄ nanorods with a ration value of 4:6 was shown in Figure 4(a). The peaks at 926.5, 830.7, 794.6 and 330.6 cm⁻¹ belongs to vibration mode of ν₁ (A_g), ν₃ (B_g), ν₃ (E_g) and ν₂ (A_g), respectively. Furthermore, a strong vibration at 925 cm⁻¹ was observed, indicating the BaWO₄ nanorods is good at stimulating Raman scattering in transient and steady-state [2] . This made it as a promising material for laser with self-raman conversion of radiation inside the active medium. The blue emission from BaWO₄ materials has been reported at low temperatures in the literature [18] [19] [20] . Interest- ingly, as shown in Figure 4(b), a broad emission band extended from 396 nm to 498 nm (peaked at approximately 425 nm) was observed when the BaWO₄ nanorods excited at 270 nm. The blue emission from BaWO₄ nanorods is known to be due to radiative transitions within molecular complexes. Hence, a similar mechanism for tungstate materials has been reported in the literature [8] [21] [22] [23] .

In the present study, BaWO₄ nanoparticles have been prepared in water-in-oil (W/O) microemulsion systems composed of 1,4-dioxane and water with varied volume ratios. The results of typical TEM images indicated that the concentra-

tion of 4-dioxane played a crucial role in the formation of BaWO₄ nanorods with different morphologies. Thus, the addition of 1,4-dioxane should be controlled. Furthermore, the Raman spectra of the produced BaWO₄ nanorods indicated that it is a promising material for laser with self-raman conversion of radiation inside the active medium.

This work was financially supported by the Natural Science Foundation of Jiangsu Province (13KJB150023, 15KJB210003, BK20150976), and the Natural Science Foundation of China (41501239).

BaWO₄ nanorods have been successfully synthesized.

The ratio of 4-dioxane and water played the key role.

The bands of produced BaWO₄ nanorods vibrated strongly at 925 cm⁻¹.

Zhang, J., Zhu, X.S., Huang, H.Y. and Zhang, Y.P. (2017) Synthesis of Crystallized BaWO₄ Nanorods in a Microemulsion System. Advances in Chemical Engineering and Science, 7, 228- 234. https://doi.org/10.4236/aces.2017.72017