Materials Sciences and Applications
Vol.5 No.1(2014), Article ID:41961,7 pages DOI:10.4236/msa.2014.51003

Preparation of Microcapsules Containing Water Droplets Stabilized with Solid Powder and Application to Blowing Agent

Daisuke Nakamura1, Hiroshi Yokoyama2, Yoshinari Taguchi1, Masato Tanaka1*

1Department of Chemistry and Chemical Engineering, Niigata University, Niigata, Japan; 2Department of Management Information, Niigata University of Management, Niigata, Japan.

Email: *tanaka@eng.niigata-u.ac.jp

Copyright © 2014 Daisuke Nakamura et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. In accordance of the Creative Commons Attribution License all Copyrights © 2014 are reserved for SCIRP and the owner of the intellectual property Daisuke Nakamura et al. All Copyright © 2014 are guarded by law and by SCIRP as a guardian.

Received October 21st, 2013; revised November 30th, 2013; accepted December 23rd, 2013

KEYWORDS

Water Containing Microcapsules; Suspension Polymerization; Multiple Emulsion; Particulate Surfactant; Blowing Agent

ABSTRACT

We have tried to prepare the microcapsules containing water droplets stabilized with solid powder by utilizing the (W/O)/W emulsion. The water droplets as core material were stabilized in the monomer droplets with titanium dioxide (TiO2) as a particulate surfactant. Before adding the TiO2 powder into the monomer phase, the powder was modified with triethoxyvinylsilane to adjust the degree of hydrophobicity and to promote adhesion on the interface between the inner water phase and the monomer phase in the (W/O) emulsion. It was investigated how the degree of hydrophobicity of the TiO2 powder affected the stability of water droplets in the (W/O) emulsion and the (W/O) droplets in the (W/O)/W emulsion. Moreover, the microcapsule diameters were measured before and after the expansion operation where the water droplets microencapsulated were applied as a blowing agent. The expansion ratio was increased with increase in the stability of the water droplets and the amount of water microencapsulated.

1. Introduction

Microcapsules containing water as a core material have been applied in the various fields such as pharmacy, adhesives, agricultural medicine, cosmetics, food and so on, because water is able to dissolve various materials of inorganic and organic substances [1,2]. There are many reports [3-6] with respect to microencapsulation of water, in which water as the core material has been mainly microencapsulated by using the multiple emulsion like the (W/O)/W emulsion.

There is the suspension polymerization method as a typical method for preparing the microcapsules containing the water phase by utilizing the (W/O)/W emulsion.

In the preparation of microcapsules containing water with the suspension polymerization method, it is important to form the stable (W/O) dispersion, where the water phase (W) is the core material and the oil phase (O) is the polymerizable monomer. For this purpose, the oil soluble surfactant species have been inevitably added and higher mechanical energy has been loaded. Then, the stability of (W/O)/W emulsion has been obtained by adding the water soluble surfactant into the continuous water phase under the optimum stirring conditions.

Tanaka et al. [7-9] have investigated the effect of solid powder on the stability of suspension polymerization of styrene, where various solid powders such as magnetite, carbon black, sulfur, cupperic oxide were added. Furthermore, they have prepared the polystyrene core/magnetite shell particles by suspension polymerization of styrene where magnetite was added into the (O/W) emulsion and acted as a particulate surfactant [10-13]. However, there are few reports which have investigated the effect of solid powder on the stability of water droplets in the (W/O) emulsion and prepared the microcapsules containing water as a core material. In this case, it is necessary to investigate how the amount of solid powder adhered on the surface of water droplets affects the stability of (W/O) emulsion, because the amount of solid powder adhered on the surface of water droplets is dependent on the contact angle of solid powder to the interface.

Namely, the effect of the degree of hydrophobicity of solid powder on the stability of water droplets in the (W/O) emulsion must be investigated in detail.

The purposes of this study are to investigate the stabilizing effect for the (W/O) and the (W/O)/W emulsion with the TiO2 powder modified by the coupling agent, to prepare the microcapsules containing water and to apply the microencapsulated water as a blowing agent for the preparation of expanded polystyrene.

2. Experiment

2.1. Materials

Materials used to prepare the microcapsules containing water by the suspension polymerization method are as follows.

TiO2 as a particulate surfactant

Titanium dioxide (TiO2) with the mean diameter of 21 nm was added in the (W/O) emulsion. The TiO2 powder was modified with triethoxyvinylsilane of a coupling agent to give the various degree of hydrophobicity. Anhydrous toluene was used as the solvent to modify the TiO2 powder. Methanol was used to wash the TiO2 powder modified. As an oil soluble surfactant, polygrycerinester (Poem PR-100-Riken Vitamine Ltd.) was used.

Preparation of Microcapsules

Styrene monomer (st) was used to form the microcapsule shell together with trimethyrol propane triacrylate (TMPTA) of a bridging agent.

Polymerization initiator was 2-2 Azobis (2,4-diamethyl varellonitril)(V-65) which was used as received.

Polyvinyl alcohol (PVA: degree of polymerization 500) was used as a water soluble stabilizer and dissolved in the continuous water phase of distilled water.

2.2. Modification of TiO2 Powder

After the TiO2 powder of 10 g was added in anhydrous toluene of 300 cm3, this slurry was heated to 109˚C in the oil bath. Then, triethoxyvinylsilane of a given concentration was poured to modify the TiO2 powder and the modification reaction was conducted for 5 h under temperature of 109˚C and stirring of impeller speed of 200 rpm with a six bladed disc turbine impeller of diameter of 5.0 cm. After the reaction, the TiO2 powder was washed twice with methanol and filtered out. In this modification process of the TiO2 powder, the concentration of coupling agent was changed from 0 to 0.1 mol/l-toluene.

2.3. Preparation of Microcapsules

Figure 1 shows the flow chart for preparing the microcapsules containing water as a core material. The TiO2 powder modified, the oil soluble surfactant and the polymerization initiator (V-65) were added in the monomer mixture of st and TMPTA beforehand. Water of given volume was added into the monomer mixture and then, agitated with the rotor-stator homogenizer to form the (W/O) emulsion for five min.

The (W/O) emulsion prepared thus was poured into the continuous water phase dissolving PVA of a given concentration under stirring of impeller speed of 250 rpm to form the (W/O/W) emulsion. Then, suspension polymerization was performed for 8 h under the conditions of 70˚C and the impeller speed of 250 rpm with the six bladed disc turbine impellers. After the suspension polymerization process, the microcapsules containing water were filtered out and washed with distilled water. In this fundamental operation, the concentration of coupling agent was mainly changed to give the TiO2 powder the various degree of hydrophobicity. Table 1 shows the experimental conditions adopted in this study.

Figure 1. Schematic flow chart for preparing microcapsules containing water.

Table 1. Experimental conditions.

2.4. Characterization

Water content of microcapsules

The water content (Fw) of microcapsules prepared was calculated by Equation (1).

(1)

where Wo and Wt are the weight of microcapsules before and after drying at 60˚C for 1h, respectively.

Measurement of diameter distributions and mean diameters

The diameter distributions and mean diameters (the Sauter diameter) of water droplets in the (W/O) emulsion and the microcapsules were obtained by directly measuring the diameters of about 100 water droplets and microcapsules from their microscopic photographs.

Observation of surface and cross section of microcapsules

The surface and inner structure of microcapsules were observed by scanning electron microscope (JSM-5800, JEOL Ltd.).

The dispersion features of the TiO2 powder in the matrix polymer of microcapsules were observed by electron probe microanalyzer (EPMA: XA-8900, TEOL Ltd.).

Expansion ratio

The expansion operation was conducted to investigate whether water microencapsulated acts as a blowing agent or not. Namely, the microcapsules were added into the oil bath at temperature of 130˚C for 1 h. Then, the diameters of microcapsules were measured from microscopic photographs. The expansion ratio was defined as Equation (2).

(2)

where VO and Vt are the volume of microcapsules before and after expansion operation.

Drying rate

The microcapsules of a given weight were dried at temperature of 50˚C and the weight of microcapsules was measured at constant time interval during 24 h.

From these results, the drying rate was estimated.

3. Results and Discussion

3.1. Effect of Solid Powder on Stability of Multiple Emulsion

Generally, the mechanism of the effect of solid powder on the stability of liquid droplets in Pickering emulsion is described as shown in Figure 2. Namely, it is necessary for solid powder to adhere on the surface of droplets as shown in Figure 2(a), and to protect coalescence between the droplets as shown in Figure 2(b).

If no solid powders adhere on the surface of droplets, where solid powder has to disperse in the continuous water phase (in the case of more hydrophilic solid powder) or in the oil droplet (in the case of more hydrophobic solid powder as shown in Figure 2(c) ), the droplets may coalesce each other to form the larger droplets as shown in Figure 2(c).

According to this stabilizing mechanism of solid powder, it was tried to investigate with the preliminary test whether the stabilizing effect of the TiO2 powder modified in the (W/O)/W emulsion was observed or not. These results are shown in Figure 3. Namely, first the (W/O) emulsion was formed by adding the TiO2 powder, water and oil soluble surfactant into the monomer mixture and agitating with homogenizer. Then, the (W/O)/W emulsion was formed by pouring the (W/O) emulsion into the continuous water phase as shown in Figure 3(a).

If the TiO2 powder is not modified and more hydrophilic or more hydrophobic, as no TiO2 powder adheres on the surface of water droplets and on the interface between the oil phase and the continuous water phase, the (W/O)/W emulsion has to be immediately broken. Figure 3(b) is the photograph showing the (W/O)/W emulsion broken, where the TiO2 powder and the oil droplets are dispersing in the water phase which is colored white by the TiO2 powder.

On the other hand, if the TiO2 powder is suitably modified and proper hydrophobic, as the TiO2 powder may adhere on the surface of core water droplets and on the interface between the surface of oil droplet and the

Figure 2. Stabilizing mechanism with solid powder.

Figure 3. Effect of TiO2 powder on stability of (W/O)/W emulsion.

continuous water phase, coalescence between the water droplets and between the oil droplets has to be protected. In this case, the (W/O)/W emulsion is stabilized as shown in Figure 3(c), in which the oil droplets become white because of dispersion of core water droplets and the TiO2 powder. From these results, it is found that the (W/O)/W emulsion is able to be stabilized by the TiO2 powder with the proper hydrophobicity.

3.2. Effect of TiO2 Powder on Stability of (W/O) Emulsion

The effect of the TiO2 powder modified on the stability of the (W/O) emulsion was investigated by measuring the transient diameters (dw) of core water droplets as shown in Figure 4. Namely, the core water phase was poured into the monomer mixture in which the TiO2 powder modified was dispersed to prepare the (W/O) dispersion by agitation with the rotor stator homogenizer. Then, the water droplets were sampled out and poured into the monomer mixture dissolving the oil soluble surfactant (1.0 wt%) to prevent from coalescing. After this, the photographs of water droplets were taken as rapid as possible. From these photographs, the mean diameters of water droplets were measured as in the previous study [14,15].

Figure 5 shows the transient diameters of core water droplets formed by adding the TiO2 powder modified with the coupling agent of various concentrations. It is found that the mean diameters of core water droplets increase with the elapsed time and the higher the concentration of coupling agent, the slower the diameters increase. Also, if the TiO2 powder unmodified was added, the (W/O) emulsion was immediately broken and the diameters of water droplets were not able to be measured. From these results, the more hydrophobic TiO2 powder is found to stabilize the (W/O) emulsion.

3.3. Observation of Microcapsules

Figure 6 shows the SEM photographs of microcapsules prepared by adding the TiO2 powder modified with the coupling agent of various concentrations.

Figure 4. Observation of effect of TiO2 powder on stability of (W/O) emulsion.

Figure 5. Transient diameters of core water droplets.

Figure 6. Observation of microcapsules.

The surfaces (a-1, b-1, c-1) of microcapsule are found to be smooth at the every preparation conditions. However, many holes, in which core water may be microencapsulated, are observed in the inner structure (a-2, b-2, c-2) of microcapsules.

From the characteristic X-ray images (TiKα) of the inner structure (a-3, b-3, c-3), it is found that the TiO2 powder adheres on the interfaces between the core water droplet and the monomer phase and between the monomer phase and the outer water phase.

Moreover, the higher the concentration of coupling agent, the larger the TiO2 powder adhered on the interface. This phenomenon may be considered to be attributable to the fact that the TiO2 powder modified with the coupling agent of the concentration of 0.10 mol/l may have the suitable contact angle to effectively adhere on the interface between the water phase and the monomer phase as shown in Figure 6(d).

3.4. Effects on the Mean Diameters of Microcapsules and Core Water Droplets and the Water Content

Figure 7 shows the effects of the concentration of coupling agent on the mean diameters of microcapsules (dp) and core water droplets (dw) and the water content (Fw).

The mean diameters (dp) of microcapsules are found to decrease from 200 μm to 70 μm with the concentration of coupling agent. As the TiO2 powder comes to have the suitable contact angle to effectively adhere on the interface, the stability of both the core water droplets and the monomer droplets is increased to prevent these droplets from coalescing.

The water content (Fw) slighly increases from 35 wt% to 38 wt% with the concentration of coupling agent because of increase in stability of the (W/O) emulsion.

On the other hand, as the stability of core water droplets increases with the concentration of coupling agent, the diameters of core water droplets may decrease.

3.5. Dependence of Drying Rate on Water Content

Figure 8 shows the dependence of the drying rate (Rd) on the water content (Fw). The drying rate increases with the water content. This may be considered to be attributable to the fact that the core water is easily released, because the shell thickness has to decrease with the water content.

However, although the water content increases with the concentration of coupling agent because of increase

Figure 7. Effects of concentration of coupling agent on dp, dw and Fw..

Figure 8. Dependence of drying rate on water content.

in stability of the (W/O) emulsion, the drying rate decreases with the concentration of coupling agent due to the same reason as stated just above.

This phenomenon may be attributable to the fact that as the TiO2 powder modified with the coupling agent of higher concentration comes to largely adhere on the interface, this adhesion layer composed of the more hydrophobic TiO2 powder may prevent water from diffusing through the polymer shell as shown in Figure 8.

3.6. Application of Microencapsulated Water to Blowing Agent

We have tried to apply the microencapsulated water to the blowing agent. Namely, the microcapsules containing water were added into the silicon oil at temperature of 130˚C for 1h as shown in Figure 9(a) and the diameters of microcapsules were measured from their photographs. Figure 9(b) shows the SEM photographs of the surface (a-1, b-1) and cross section (a-2, b-2) of microcapsules before and after expansion operation.

It is found that the diameters of microcapsules and inner holes after the expansion operation become larger than those before the expansion operation. This enlargement of diameters of microcapsules and inner holes could be considered to be attributable to expansion by the microencapsulated water.

Figure 10 shows the comparison of volume of microcapsules before and after expansion operation. The volume of microcapsules after the expansion operation is found to be 2.57 times that before expansion.

From this result, we are able to understand that the water droplets stabilized by the TiO2 powder act as a blowing agent and the TiO2 powder adhered on the interface controls the diffusion velocity of water molecule through the polymer shell.

Figure 9. Expansion operation and SEM photographs of microcapsule before and after expansion.

Figure 10. Comparison of volume of microcapsules before and after expansion operation.

4. Conclusions

We have tried to prepare the microcapsules containing water as the core material by using the stabilizing effect of the TiO2 powder in the (W/O) and the (W/O)/W emulsion and obtained the following results.

1) The microcapsules containing water were able to be prepared by the suspension polymerization method.

2) The diameters of core water droplets were decreased with the concentration of the coupling agent because of increase in stability of (W/O) dispersion.

3) The water content was increased with the degree of hydrophobicity of the TiO2 powder.

4) The microencapsulated water acted as a blowing agent.

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NOTES

*Corresponding author.