KR20120035469A - Method for fabrication of microparticles with superhydrophobic surface structures and coating them on substrates - Google Patents

Abstract

The present invention relates to a method for preparing microparticles having a superhydrophobic surface and coating the same on a flat or flexible substrate, and more specifically, to (a) preparing microparticles having a structure formed by colloidal particles, and (B) dispersing the superhydrophobic microparticles in a dispersion medium, a photopolymerization dispersion medium or a volatile dispersion medium, and (c) the superhydrophobic microparticles A method of preparing microparticles having a superhydrophobic surface comprising applying a dispersed solution to a substrate and coating the same on a substrate. In addition, when dispersed in a photocurable or volatile dispersion medium is characterized in that the step of evaporating the ultraviolet irradiation or the applied solution to form a film.
The substrate to which the superhydrophobic microparticles of the present invention are applied can implement spherical microparticles on any surface. In addition, the present invention is simpler and more economical than the conventional substrate manufacturing method.

Description

Method for fabricating microparticles with superhydrophobic surface structure and coating on substrate {Method for fabrication of microparticles with superhydrophobic surface structures and coating them on substrates}

The present invention relates to a method for preparing microparticles having a superhydrophobic surface and coating the same on a flat or flexible substrate, and more specifically, (a) preparing microparticles having a structure formed by colloidal particles, and Preparing a microparticle having a superhydrophobic surface through a reactive etching process, (b) dispersing the superhydrophobic microparticles in a dispersion medium, and (c) dispersing the superhydrophobic microparticle dispersion solution on a substrate. The present invention relates to a method for preparing microparticles having a superhydrophobic surface and coating the same on a substrate.

Recently, with the rapid development of science and technology, many functional materials have been developed. These functional materials are tailored to their intended use and are used in specific environments. However, as many materials are exposed to the use environment for a long time, the physical, chemical, and biological surfaces are damaged, and as a result, the original function is lost. The most common example is the loss of surface properties of materials due to moisture, fine dust, or organisms in the atmosphere. Therefore, many researchers today are attempting to protect these materials from the external environment. The most attempted solution to these problems is to treat the surface of the material to have superhydrophobic properties. The superhydrophobic surface treatment can prevent the problem of fog caused by moisture in the air or biofouling caused by living organisms. Also, as the water droplets do not get wet on the surface and roll down, they can remove the fine dust on the surface by themselves. For this reason, many scientists today are attempting to treat superhydrophobic surfaces of materials in a variety of ways.

Conventional manufacturing method for forming a superhydrophobic surface has been used to control the surface properties through a chemical or physical treatment on a solid substrate, which is complicated manufacturing process, difficult process conditions, irregular or irregular surface of the material There was a problem of having to make regular rough surfaces. In addition, it is difficult to obtain desired surface properties for all kinds of materials because a method of controlling the surface properties of each type is devised according to the shape of the substrate and the characteristics of the substrate material.

The process for producing superhydrophobic surfaces employs methods of coating hydrophobic chemicals or forming nano-sized or micro-sized structures on flat solid surfaces. It is a method for producing irregular or regular rough surfaces in such a way as to implement superhydrophobic surfaces on artificially flat solid surfaces. An article published in Langmuir, a prominent professional magazine in the colloidal field [Sung-Gyu Park, Su Yeon Lee, Se Gyu Jang and Seung-Man Yang, "Perfectly Hydrophobic Surfaces with Patterned Nanoneedles of Controllable Features," Langmuir, 26, 5295-5299 (2010)], a single layer of silica microparticles are prepared on a polymer having a thickness larger than the diameter of the particles, and the temperature is raised above the glass transition temperature of the polymer to impregnate the particles with a polymer layer. Subsequently, the particles are removed and the plasma of SF6 gas is exposed, creating a patterned surface of nanoneedle shape. However, this method has a disadvantage in that it is easy to prepare a superaqueous solid surface having a very large contact angle, but is only applicable to the solid surface, so it is difficult to apply to a flexible substrate or an interface between two liquids that are not mixed.

Recently, a method for producing Janus microparticles having hydrophilic and hydrophobic surfaces using photopolymerizable droplets has been developed. Presented in Angewandte Chemie International Edition, the leading international journal in chemistry [Shin-Hyun Kim, Su Yeon Lee, and Seung-Man Yang, "Janus Microspheres for Highly Flexible and Impregnable Water-Repelling Interface," Angewandte Chemie International Edition, 49 , 2535-2538 (2010)], a photopolymerizable resin was prepared as droplets of uniform size in water dispersed with a surfactant using a microfluidic device and photopolymerized to produce polymer spherical microparticles. In particular, hydrophilic and hydrophobic surfaces can be formed in each hemisphere by removing particles at the interface and exposing SF6 plasma to spherical microparticles. This can form a superhydrophobic barrier on the water surface in the direction of the hemisphere depending on the surface properties of each of the Janus microparticles at the water-air interface. However, Janus microparticles having these two surface characteristics have a disadvantage in that a process of arranging the orientations of the two hemispheres in a desired direction is required to make the superhydrophobic surface.

It is a basic object of the present invention to provide a method for coating superhydrophobic microparticles on a substrate, the method comprising preparing microparticles having a superhydrophobic surface and applying the same to a substrate.

Another object of the present invention is to prepare a microparticle having a structure formed by the colloidal particles (a), remove the particles and to produce a microparticle having a superhydrophobic surface through a reactive etching process, (b) the superhydrophobic fine Dispersing the particles in a dispersion medium, (c) to provide a method for coating the superhydrophobic microparticles to the substrate comprising the step of applying a solution in which the superhydrophobic microparticles are dispersed.

Still another object of the present invention is to prepare a microparticle having a structure formed by the colloidal particles, removing the particles and producing a microparticle having a superhydrophobic surface through a reactive etching process, (b) the superhydrophobic Dispersing the fine particles in a photocurable dispersion medium, (c) applying a solution containing the superhydrophobic microparticles to a substrate, and (d) irradiating the applied solution with ultraviolet rays to form a film. It is to provide a method for coating a superhydrophobic microparticles on a substrate.

Still another object of the present invention is to prepare a microparticle having a structure formed by the colloidal particles, removing the particles and producing a microparticle having a superhydrophobic surface through a reactive etching process, (b) the superhydrophobic Dispersing the fine particles in a volatile dispersion medium, (c) applying a solution containing the superhydrophobic microparticles onto a substrate, and (d) evaporating the applied solution to form a superhydrophobic microparticle layer. It is to provide a method for coating a superhydrophobic microparticles on a substrate.

The basic object of the present invention can be achieved by providing a method for coating superhydrophobic microparticles on a substrate, which comprises preparing microparticles having a superhydrophobic surface and applying them to the substrate.

Another object of the present invention described above is (a) preparing microparticles having a structure formed by colloidal particles, and then removing the particles and preparing microparticles having a superhydrophobic surface through a reactive etching process, (b 1) dispersing the superhydrophobic microparticles in a dispersion medium, and (c) applying a solution in which the superhydrophobic microparticles are dispersed to the substrate. have.

Still another object of the present invention is to prepare a microparticle having a superhydrophobic surface by (a) preparing a microparticle having a structure formed by the colloidal particles, and then removing the particles and a reactive etching process, (b) the Dispersing superhydrophobic microparticles in a volatile dispersion medium, (c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate, and (d) evaporating the applied solution to form a superhydrophobic microparticle layer. It can be achieved by providing a method for coating a substrate with superhydrophobic microparticles comprising.

The present invention is a method for changing the chemical composition of the surface and to prepare a hydrophobic structure of the surface for producing a conventional superhydrophobic surface by using a spherical microparticles having a superhydrophobic surface structure prepared before Hydrophobic surfaces can be implemented. Therefore, it is possible to surface-treat without restrictive conditions in the manufacture of superhydrophobic surfaces on flat or flexible substrates, and the manufacturing method of pre-fabricated superhydrophobic microparticles is much simpler than the surface treatment on conventional substrates. And the process time can be greatly reduced.

1 is a schematic view showing a method for producing microparticles having a superhydrophobic surface.
2 is a schematic view showing a method of coating a photocurable solvent in which superhydrophobic microparticles are dispersed on a desired surface by spraying or spin coating.
3 is a schematic view showing a method of coating a desired surface by spraying or spin coating a volatile solvent in which superhydrophobic microparticles are dispersed.
Figure 4 is an optical micrograph of the surface coated with microparticles having a superhydrophobic surface prepared.
FIG. 5 is an electron micrograph of a surface coated with microparticles having a superhydrophobic surface.
FIG. 6 is a photograph of water droplets formed on a surface coated with microparticles having a superhydrophobic surface.
FIG. 7 is a cross-sectional photograph of water droplets formed on a surface coated with microparticles having a superhydrophobic surface.
FIG. 8 is a cross-sectional photograph of water droplets formed on a substrate after RIE treatment to microparticles having a smooth surface having no hydrophobic nanostructure and then applied to the substrate.

The present invention shows a surface coating method using super hydrophobic microparticles.

The present invention represents a surface coating method of coating on a flat substrate or a flexible substrate using superhydrophobic microparticles.

In the above, the size of the superhydrophobic microparticles may be used 5㎛ to 1mm.

The superhydrophobic microparticles in the above can be used having a porous structure.

In the above, the superhydrophobic microparticles having a porous structure may use a surface treated with a hydrophobic chemical.

In the above, the surface of the superhydrophobic microparticles may be formed of a hydrophobic nanostructure.

The superhydrophobic microparticles may be a polymer material.

The superhydrophobic microparticles may be a polymer including an acrylate group.

The present invention (a) preparing a microparticle having a structure formed by the colloidal particles, removing the particles and producing a microparticle having a superhydrophobic surface through a reactive etching process,

(b) dispersing the superhydrophobic microparticles in a dispersion medium,

(c) a method of coating a superhydrophobic microparticles on a substrate, the method comprising applying a solution in which the superhydrophobic microparticles are dispersed to a substrate.

The solution in which the superhydrophobic microparticles are dispersed may be applied to a substrate by spin coating.

The solution in which the superhydrophobic microparticles are dispersed may be applied to a substrate by spraying.

The present invention (a) preparing a microparticle having a structure formed by the colloidal particles, removing the particles and producing a microparticle having a superhydrophobic surface through a reactive etching process,

(b) dispersing the superhydrophobic microparticles in a photocurable dispersion medium,

(c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate,

(d) a method of coating a substrate with superhydrophobic microparticles comprising the step of forming a film by irradiating the applied solution with ultraviolet rays.

The photocurable dispersion medium may be a polymer including an acrylate group.

The photocurable dispersion medium in which the superhydrophobic microparticles are dispersed is 5% (v / v) to 70% (v / v) of the superhydrophobic microparticles, and 95% (v / v) to 30% of the photocurable dispersion medium. (v / v) may include.

The present invention (a) preparing a microparticle having a structure formed by the colloidal particles, removing the particles and producing a microparticle having a superhydrophobic surface through a reactive etching process,

(b) dispersing the superhydrophobic microparticles in a volatile dispersion medium,

(c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate,

and (d) evaporating the applied solution to form a superhydrophobic microparticle layer.

The volatile dispersion medium in which the superhydrophobic microparticles are dispersed includes 5% (v / v) to 70% (v / v) of the superhydrophobic microparticles, and 95% (v / v) to 30% (v) of the volatile dispersion medium. / v).

Hereinafter, the present invention will be described in more detail.

The basic object of the present invention can be achieved by providing a method for coating superhydrophobic microparticles on a substrate, which comprises preparing microparticles having a superhydrophobic surface and applying the same to a substrate.

The size of the microparticles having the superhydrophobic surface structure of the present invention is preferably 5㎛ to 1mm. In addition, the microparticles having the superhydrophobic surface structure of the present invention may have a superhydrophobic property by introducing a porous structure or a hydrophobic chemical. In addition, the microparticles having the superhydrophobic surface structure of the present invention may exhibit superhydrophobicity in whole or in part on the surface of the microparticles.

The microparticles having a superhydrophobic surface structure increase the porosity by using a reactive ion etching process to the porous microparticles obtained by curing the photocurable polymer in which the colloidal particles are dispersed through ultraviolet rays and selectively removing the colloidal particles. This can be achieved by treating the surface of the microparticles with a material.

The superhydrophobic microparticles preferably contain 5% (v / v) to 70% (v / v) of the colloidal particles and 95% (v / v) to 30% (v / v) of the polymer. In addition, the polymer in which the colloidal particles of the present invention are dispersed is a photocured polymer, and may be used without limitation as long as the colloidal particles are spontaneously dispersed when the colloidal particles are dispersed and photocured. Preferably, a photocured polymer containing an acrylate group can be used. The colloidal particles can be selected from silica, titanium dioxide, polystyrene or polymethylmethacrylate. In addition, the size of the colloidal particles is preferably 20nm to 10㎛.

Another object of the present invention described above is (a) preparing microparticles having a structure formed by colloidal particles, removing particles and preparing microparticles having a superhydrophobic surface through a reactive etching process, (b) the Dispersing the superhydrophobic microparticles in a dispersion medium, (c) it can be achieved by providing a method for coating the superhydrophobic microparticles on the substrate comprising the step of applying a solution in which the superhydrophobic microparticles are dispersed.

The dispersion medium in which the superhydrophobic microparticles are dispersed may be used without limitation as long as the superhydrophobic microparticles are well dispersed.

The method of applying the solution in which the superhydrophobic microparticles are dispersed to the substrate may be used without limitation as long as the method is uniformly applied to the substrate. Preferably, spin coating or spraying may be used.

Another object of the present invention described above is (a) preparing microparticles having a structure formed by colloidal particles, and then removing the particles and preparing microparticles having a superhydrophobic surface through a reactive etching process, (b Dispersing the superhydrophobic microparticles in a photocurable dispersion medium, (c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate, and (d) irradiating the applied solution with ultraviolet rays to form a film. It can be achieved by providing a method for coating a substrate with superhydrophobic microparticles comprising the step.

The photocurable dispersion medium may be used without limitation as long as it is a solution in which superhydrophobic microparticles can be dispersed well. Preferably, a photocured polymer containing an acrylate group can be used.

The photocurable dispersion medium in which the superhydrophobic microparticles are dispersed may contain 5% (v / v) to 70% (v / v) of the superhydrophobic microparticles, and 95% (v / v) to 30% of the photocurable dispersion medium ( v / v). When the superhydrophobic microparticles are within 5% (v / v), the superhydrophobic microparticles are not evenly applied when the substrate is applied to the substrate, and thus the surface has a superhydrophobic characteristic. In addition, when the superhydrophobic microparticles are 70% (v / v), the viscosity of the solution is too high, making it difficult to distribute the microparticles evenly on the surface. In addition, when the photocurable dispersion medium is more than 95% (v / v) there is a limit in showing the superhydrophobic characteristics because the superhydrophobic microparticles are not evenly applied when applied to the substrate. In addition, when the photocurable dispersion medium is within 30% (v / v), it is difficult to distribute the fine particles evenly on the surface because the viscosity of the solution is too high.

Still another object of the present invention is to prepare a microparticle having a superhydrophobic surface by (a) preparing a microparticle having a structure formed by the colloidal particles, and then removing the particles and a reactive etching process, (b) the Dispersing superhydrophobic microparticles in a volatile dispersion medium, (c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate, and (d) evaporating the applied solution to form a superhydrophobic microparticle layer. It can be achieved by providing a method for coating a substrate with superhydrophobic microparticles comprising.

The volatile dispersion medium may be used without limitation as long as it is a solution in which fine particles having a superhydrophobic surface structure can be dispersed well.

The volatile dispersion medium in which the superhydrophobic microparticles are dispersed comprises 5% (v / v) to 70% (v / v) of the superhydrophobic microparticles, and 95% (v / v) to 30% (v / v) of the volatile dispersion medium. v) preferably. When the superhydrophobic microparticles are within 5% (v / v), the superhydrophobic microparticles are not evenly applied when the substrate is applied to the substrate, and thus the surface has a superhydrophobic characteristic. In addition, when the superhydrophobic microparticles are 70% (v / v), the viscosity of the solution is too high, making it difficult to distribute the microparticles evenly on the surface. In addition, when the volatile dispersion medium is more than 95% (v / v) there is a limit to the superhydrophobic characteristics because the surface is not evenly applied superhydrophobic fine particles when applied to the substrate. In addition, when the volatile dispersion medium is within 30% (v / v), the viscosity of the solution is too high, it is difficult to distribute the fine particles evenly on the surface.

The formed superhydrophobic microparticle layer may have a single layer or a multilayer structure.

Hereinafter, the present invention will be described in more detail with reference to the following examples and drawings. However, the following description of the embodiments and drawings is only intended to specifically describe the specific embodiments of the present invention, it is not intended to limit or restrict the scope of the present invention to the contents described therein.

Example 1 Preparation of Super Hydrophobic Substrate Using Spin Coating of Superhydrophobic Microparticles Dispersed in Photocurable Dispersion Medium

1 ml of a dispersion obtained by dispersing 400 nm-sized silica particles prepared by the Stover-Pink-This method in a volume ratio of 1: 9 was introduced into 10 ml of an aqueous 1 wt% Pluronic F108 (surfactant) solution. After shaking the mixture, a mercury arc lamp was used to cure by irradiating 40 mW / cm ² ultraviolet light for 10 seconds. The photonic crystal mixture thus obtained was washed with distilled water to remove the surfactant and dried.

The spherical photonic crystal was placed in a 5wt% HF solution and left for 6 hours to remove silica particles, which were then etched using SF6 gas in a RIE chamber. The superhydrophobic microparticles thus prepared were dispersed in ETPTA at a concentration of 30% (v / v), and spin-coated at 1000 rpm on the wafer substrate to apply superhydrophobic microparticles. The applied superhydrophobic microparticles and ETPTA mixture was cured by irradiating UV light of 40 mW / cm ² for 10 seconds using a mercury arc lamp. As a result, superhydrophobic microparticles were immobilized on the ETPTA dispersion phase evenly distributed on the substrate. The superhydrophobic microparticles applied were observed through an optical microscope and an electron microscope (FIGS. 4 and 5).

Water droplets were dropped onto the substrate to which the superhydrophobic microparticles were applied (FIG. 6, 7). Compared to the substrate coated with the microparticles having no hydrophobic nanostructure (FIG. 8), the hydrophilic substrate showed the superhydrophobicity when the superhydrophobic microparticles were applied to the water droplets.

Example 2 Preparation of Super Hydrophobic Substrate Using Spraying of Superhydrophobic Microparticles Dispersed in Photocurable Dispersion Medium

1 ml of a dispersion obtained by dispersing 400 nm-sized silica particles prepared by the Stover-Pink-This method in a volume ratio of 1: 9 was introduced into 10 ml of an aqueous 1 wt% Pluronic F108 (surfactant) solution. After shaking the mixture, a mercury arc lamp was used to cure by irradiating 40 mW / cm ² ultraviolet light for 10 seconds. The photonic crystal mixture thus obtained was washed with distilled water to remove the surfactant and dried.

The spherical photonic crystal was placed in a 5wt% HF solution and left for 6 hours to remove silica particles, which were then etched using SF6 gas in a RIE chamber. The superhydrophobic microparticles thus prepared were dispersed in ETPTA at a concentration of 30% (v / v) and then sprayed onto the substrate through a nozzle at a pressure of 40 psi. The applied superhydrophobic microparticles and ETPTA mixture was cured by irradiating UV light of 40 mW / cm ² for 10 seconds using a mercury arc lamp. As a result, superhydrophobic microparticles were immobilized on the ETPTA dispersion phase evenly distributed on the substrate. It was confirmed that the superhydrophobic property of the prepared substrate was the same as in Example 1.

Example 3 Preparation of Super Hydrophobic Substrate Using Spin Coating of Superhydrophobic Microparticles Dispersed in Volatile Dispersion Medium

1 ml of a dispersion obtained by dispersing 400 nm-sized silica particles prepared by the Stover-Pink-This method in a volume ratio of 1: 9 was introduced into 10 ml of an aqueous 1 wt% Pluronic F108 (surfactant) solution. After shaking the mixture, a mercury arc lamp was used to cure by irradiating 40 mW / cm ² ultraviolet light for 10 seconds. The photonic crystal mixture thus obtained was washed with distilled water to remove the surfactant and dried.

The spherical photonic crystal was placed in a 5wt% HF solution and left for 6 hours to remove silica particles, which were then etched using SF6 gas in a RIE chamber. The superhydrophobic microparticles thus prepared were dispersed in ethanol at a concentration of 30% (v / v), and spin-coated at 1000 rpm on the wafer substrate to apply superhydrophobic microparticles. The ethanol was then slowly evaporated at room temperature to leave only superaqueous microparticles. As a result, it was confirmed that the superhydrophobic microparticles were evenly distributed on the substrate. It was confirmed that the superhydrophobic property of the prepared substrate was the same as in Example 1.

Example 4 Fabrication of Superhydrophobic Substrates Using Spraying of Superhydrophobic Microparticles Dispersed in Volatile Dispersion Medium

1 ml of a dispersion obtained by dispersing 400 nm-sized silica particles prepared by the Stover-Pink-This method in a volume ratio of 1: 9 was introduced into 10 ml of an aqueous 1 wt% Pluronic F108 (surfactant) solution. After shaking the mixture, a mercury arc lamp was used to cure by irradiating 40 mW / cm ² ultraviolet light for 10 seconds. The photonic crystal mixture thus obtained was washed with distilled water to remove the surfactant and dried.

The spherical photonic crystal was placed in a 5wt% HF solution and left for 6 hours to remove silica particles, which were then etched using SF6 gas in a RIE chamber. The superhydrophobic microparticles thus prepared were dispersed in ethanol at a concentration of 30% (v / v) and then sprayed onto the substrate through a nozzle at a pressure of 40 psi. The ethanol was then slowly evaporated at room temperature to leave only superaqueous microparticles. As a result, it was confirmed that the superhydrophobic microparticles were evenly distributed on the substrate. It was confirmed that the superhydrophobic property of the prepared substrate was the same as in Example 1.

The method of preparing microparticles having a superhydrophobic surface of the present invention and coating the same on a flat or flexible substrate is exposed to fine dust for a long time such as the surface of an automobile, an exterior wall of a building, an outdoor advertisement, or an air filter equipment. It can be used as a coating material capable of self-cleaning of fine dust by being applied to a material that may be contaminated or deteriorated. In addition, it can be used as a coating material for anti-fog, such as windows of buildings or automobiles. In addition, the biofouling phenomenon of the functional materials used in various industrial processes can be easily coated on any material that can be used to prevent the biofouling phenomenon.

Claims (15)

Surface coating method using super hydrophobic microparticles. The surface coating method using superhydrophobic microparticles according to claim 1, wherein the superhydrophobic microparticles have a size of 5 µm to 1 mm. The surface coating method using superhydrophobic microparticles according to claim 1, wherein the superhydrophobic microparticles have a porous structure. The surface coating method using superhydrophobic microparticles according to claim 3, wherein the superhydrophobic microparticles having the porous structure are surface treated with a hydrophobic chemical. The surface coating method using superhydrophobic microparticles according to claim 1, wherein the surface of the superhydrophobic microparticles is formed of a hydrophobic nanostructure. The surface coating method using superhydrophobic microparticles according to claim 1, wherein the superhydrophobic microparticles are a polymer material. The surface coating method using superhydrophobic microparticles according to claim 6, wherein the superhydrophobic microparticles are polymers containing an acrylate group. (a) preparing microparticles having a structure formed by colloidal particles, removing particles and preparing microparticles having a superhydrophobic surface through a reactive etching process,
(b) dispersing the superhydrophobic microparticles in a dispersion medium,
(c) coating the substrate with the superhydrophobic microparticles, comprising applying a solution containing the superhydrophobic microparticles dispersed thereon onto a substrate. 9. The method of claim 8, wherein the step of applying the solution in which the superhydrophobic microparticles are dispersed to the substrate comprises applying a solution in which the superhydrophobic microparticles are dispersed to the substrate. A method of coating hydrophobic microparticles on a substrate. The method of claim 8, wherein the step of applying the solution in which the superhydrophobic microparticles are dispersed to the substrate comprises spraying the superhydrophobic microparticles dispersed solution onto the substrate. A method of coating hydrophobic microparticles on a substrate. (a) preparing microparticles having a structure formed by colloidal particles, removing particles and preparing microparticles having a superhydrophobic surface through a reactive etching process,
(b) dispersing the superhydrophobic microparticles in a photocurable dispersion medium,
(c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate,
(d) irradiating the applied solution with ultraviolet rays to form a film. 12. The method of claim 11, wherein the photocurable dispersion medium comprises an acrylate group. The photocurable dispersion medium in which the superhydrophobic microparticles are dispersed comprises 5% (v / v) to 70% (v / v) of the superhydrophobic microparticles, and 95% (v / v) of the photocurable dispersion medium. v) to 30% (v / v) comprising a method for coating a superhydrophobic microparticles on a substrate. (a) preparing microparticles having a structure formed by colloidal particles, removing particles and preparing microparticles having a superhydrophobic surface through a reactive etching process,
(b) dispersing the superhydrophobic microparticles in a volatile dispersion medium,
(c) applying a solution in which the superhydrophobic microparticles are dispersed to a substrate,
(d) evaporating the applied solution to form a superhydrophobic microparticle layer, wherein the superhydrophobic microparticles are coated on a substrate. The volatile dispersion medium in which the superhydrophobic microparticles are dispersed comprises 5% (v / v) to 70% (v / v) of the superhydrophobic microparticles, and 95% (v / v) of the volatile dispersion medium. To 30% (v / v) comprising a method for coating the superhydrophobic microparticles on the substrate.

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