Synthesis of Titanium Phosphates with Additives and Their Powder Properties for Cosmetics ()
1. Introduction
As a white pigment, titanium dioxide is used for cosmetic application [1]. This oxide is well known to have the photo catalytic activity. Therefore, a certain degree of sebum is decomposed by the ultraviolet radiation in sunlight. To repress this effect, some kinds of process are investigated and used. For example, as one of these techniques, the composite particles with silicon oxide are used [2]. However, these particles are hard materials for human face. The mild materials for human face are required as a white pigment. In addition, there was a report that microfine titanium dioxide would be adsorbed through the skin [3]. The novel white pigment that is not adsorbed is required.
Phosphates have been used for ceramic materials, catalysts, adsorbent, fluorescent materials, dielectric substances, biomaterials, for metal surface treatment, as fertilizer, detergents, food additives, in fuel cells, pigments, and other items [4-8]. It is well known that phosphate materials have high affinity for a living body. Therefore, as a novel white pigment, phosphates have a possibility for the cosmetics.
For the cosmetics, the moisture retention of materials is important to prevent the dry skin. Generally, urea is added to improve this moisture retention [9]. In previous work [10], the addition of urea had influence on the particle properties of inorganic phosphate materials. Spherical particles and large specific surface area were obtained in the preparation of lanthanum phosphate by the addition of urea. The particle shape of the pigment has influence on the smoothness of materials [11-13]. The smoothness of pigment is also important for the cosmetic applications. The white pigment with high smoothness spreads well on the skin. Further, sodium lactate and glycerin are easy to keep water in materials. Therefore, these compounds are used for cosmetics. Sodium lactate is considered to have antioxidant properties [14].
In this work, titanium phosphates were prepared from titanium chloride and phosphoric acid solution, with the addition of urea, sodium lactate, and glycerin. Their chemical composition, powder properties, photo catalytic activity, moisture retention, and smoothness of the obtained precipitates and their thermal products were studied for the cosmetic application.
2. Experimental Procedure
0.1 mol/l of titanium chloride solution was mixed with 0.1 mol/l of phosphoric acid solution in a molar ratio of Ti/P = 1/1. Urea, sodium lactate, and glycerin were added in the phosphoric acid solution to 0.5 mol/l before the mixing [10]. The mixing conditions were shown in Table 1. Then, the precipitates were filtered off, washed with water, and dried. These samples were settled as “sample A-H” in this paper.
A part of the precipitates was dissolved in hydrochloric acid solution. The ratios of phosphorus and titanium in
Table 1. Ti/P ratio in precipitates and specific surface area (SSA) of thermal products at 200˚C.
the precipitates were also calculated from ICP results of these solutions, using SPS1500VR, Seiko Instruments Inc. The chemical composition of these materials was analyzed by XRD. XRD patterns were recorded on a Rigaku Denki RINT 1200M X-Ray diffractometer using monochromated CuKα radiation. TG and DTA curves were measured with a Shimadzu DTG-60H at a heating rate of 10 K·minute–1 in air. Samples were heated at 100˚C, 200˚C, 400˚C, 600˚C in air conditions. These thermal products were also analyzed by XRD.
The powder properties of precipitates and their thermal products were estimated from SEM images, particle size distributions, and specific surface area. Scanning electron microscopy (SEM) images of titanium phosphates were observed using JGM-5510LV, JEOL Ltd. The particle size distributions of these materials were measured with laser diffraction/scattering particle size distribution HO-RIBA LA-910. The specific surface area of phosphates was calculated from the amount of nitrogen gas adsorbed at the temperature of liquid nitrogen by BET method with a Belsorp mini from Bel Japan.
The cosmetic properties were estimated by the photo catalytic activity, the moisture retention, and the smoothness. The photo catalytic activity of samples was estimated with the decomposition of methylene blue by 365 nm radiation [15,16]. As the moisture retention of samples, 0.1 g of sample was mixed with 0.03 g of water, and then evaluated their weight loss under 50% - 60% in humidity at about 20˚C. The smoothness of particles was measured on artificial leather with KES-SE objective evaluation of surface friction property, KATO Tech Co. Ltd.
3. Results and Discussion
3.1. Chemical Composition of Precipitates
Table 1 shows Ti/P ratio of precipitate calculated from ICP results. The Ti/P ratio in precipitates increased by the additives. Because all samples had higher Ti/P ratio than the Ti/P ratio of TiPO4(OH) and Ti3(PO4)4, the hydroxide was considered to form. The regularity by the kinds of the additives was not clear on these Ti/P ratios. Figure 1 shows XRD patterns of samples prepared with various additives. Samples A-F were amorphous phase, on the other hand, unknown small peaks were observed in XRD patterns of samples G and H. By heating at 400˚C, all samples were amorphous. Samples D, F, G, and H heated at 600˚C had small peak at about 26 degree.