KR101719422B1 - Porous Metal Oxide Composite Nanofibers including Nanoparticle Catalysts Functionalized by using Nanoparticle Dispersed Emulsion Solution, Gas Sensors using the same and Manufacturing Method thereof - Google Patents

Abstract

A porous metal oxide composite nanofiber including a catalyst functionalized from an emulsion spinning solution having nanoparticles dispersed therein, a gas sensor using the same, and a method of manufacturing the same. A method for preparing a porous metal oxide composite nanofiber, comprising: synthesizing a nanoparticle catalyst having a hydrophobic or hydrophilic functional group attached to a surface thereof; Dispersing the first dispersion solution using the synthesized nanoparticle catalyst; Dissolving at least one of the metal oxide precursor and the polymer in the second dispersion solution, and mixing the first dispersion solution and the second dispersion solution to each other so as to be phase-separated or layer-separated; Adding a surfactant to the mixed solution of the first dispersion solution and the second dispersion solution to prepare an emulsion solution for the first dispersion solution in a micro-droplet form; Preparing a composite nanofiber including at least one of the metal oxide precursor and the polymer by electrospinning the emulsion spinning solution, wherein the first dispersion solution is present in the form of a droplet in the form of a droplet; And a porous metal oxide composite in which the first dispersion solution is removed to form a plurality of micropores, and the nanoparticle catalyst is uniformly bound to at least one of the interior and the surface to functionalize the composite nanofiber, Nanofibers can be produced.

Description

TECHNICAL FIELD [0001] The present invention relates to a porous metal oxide composite nanofiber comprising a catalyst functionalized from an emulsion solution in which nanoparticles are dispersed, a gas sensor using the porous metal oxide composite nanofiber, same and Manufacturing Method thereof}

The present invention relates to a sensing material for a gas sensor, a gas sensor using the sensing material, and a method of manufacturing the same. Specifically, an electrospinning solution containing an emulsion solution in which nanoparticles are dispersed is prepared, Porous metal oxide nanofibers, a gas sensor using the same, and a method of manufacturing the same.

Environmental pollution has progressed along with the advancement of industry and rapid development, and the health risk caused by this has been highlighted. Air pollution problems, such as dust and smog, are emerging as serious social problems, and there is growing interest in sensor technology that can quickly detect environmentally harmful gases and provide harmful information. In addition to environmental sensors, sensor technology for monitoring gas sensors for disease diagnosis that can be applied to technologies that can diagnose diseases using human exhalation is attracting attention. Among various sensing technologies, development of a gas sensor technology that can be inserted into a portable device such as a smart phone or applicable to a wearable device is required.

Researches and developments of gas sensors based on metal oxide semiconductors have been actively pursued because they are advantageous in that they are simple and inexpensive. Particularly, attempts have been actively made to improve the sensitivity and selectivity for a specific gas by manufacturing the metal oxide semiconductor sensing material as a nanostructure and combining various metal catalysts. Such a gas sensor based on a metal oxide semiconductor exhibits sensitivity by a surface reaction. The reaction occurs when a specific gas is adsorbed and desorbed on the surface of a metal oxide semiconductor material, and the electrical resistance of the metal oxide is changed. Gas sensitivity. The gas sensor based on metal oxide semiconductor analyzes the resistance ratio when the specific gas is exposed to the resistance in air, so that the sensor system configuration is simple and easy to use because it indicates the specific gas quantitatively. In addition, since the sensor structure is simple and miniaturization is easy, attempts to commercialize it in cooperation with a smart device or a wearable device are being actively pursued.

Currently, a semiconductor type metal oxide gas sensor using resistance change is applied in various fields such as an indoor harmful environmental gas alarm, an alcohol drinking meter, and an atmospheric environment sensor. Especially, the research on the healthcare expiratory sensor that can diagnose the presence of the disease early by sensing the bio-indicator gas indicating the presence or absence of the disease of the body by analyzing the human's exhalation is receiving attention. Gases such as acetone, hydrogen sulfide, toluene, ammonia, and nitrogen monoxide in the exhalation are known as biomarkers for diabetes, bad breath, lung cancer, kidney disease and asthma, respectively, and studies for diagnosing diseases by analyzing these have been reported.

Since various bio-surface gases included in the exhalation are mixed with thousands of kinds of volatile organic compounds, it is necessary to be able to selectively detect the concentration of the desired gas. In addition, these biomass surface gases show a very low concentration in the range of 1 ppb (parts per billion) to 10 ppm (part per million) compared with the atmospheric measurement concentrations. Therefore, in order to use these gas sensors for detecting biomarkers, a sensor having a high level of sensitivity capable of measuring the concentration of ppb class is required. The response time of the gas sensor must be within a few seconds to several tens of seconds since the person exhales, and the recovery time required to recover the initial state before measurement is also within a few seconds .

However, a gas sensor based on a metal oxide semiconductor needs to be improved in terms of selectivity because it measures changes in electrical conductivity due to adsorption and desorption of gases on the surface of the sensor material. In addition, there is a disadvantage that the sensitivity to very low concentrations of gases of the order of a few ppb is not sufficient. In order to apply a gas sensor based on a metal oxide semiconductor to an exhalation sensor for health care, it is essential to improve selectivity and sensitivity, and development of a sensing material capable of solving the problem is important.

In order to improve the sensitivity of gas sensors based on metal oxide semiconductors, researches have been actively conducted to synthesize sensing materials having various nano structure shapes including nanoparticles, nanofibers, nanotubes, nanocubes, and nano hollow structures. Since nanostructure sensing materials have a larger surface area to react with the target gas than thick films, the use of nanostructure sensing materials in gas sensors based on metal oxide semiconductors, The sensitivity can be obtained. Nano-hollow structures or porous structures can be expected to have fast reaction rates because gases can easily diffuse into the sensing material.

In order to improve the sensitivity and selectivity, various catalytic materials are synthesized and bound to metal oxides. These nanoparticle catalysts are divided into the principle of chemical sensitization and electronic sensitization according to the principle. The chemical sensitization method improves the characteristics of the gas sensor by increasing the concentration of oxygen ions on the surface of the material by using a metal catalyst such as platinum (Pt), gold (Au) and the like. The electronic sensitization method is palladium (Pd), nickel ), Cobalt (Co), and silver (Ag), which are formed by forming metal oxides such as PdO, NiO, Co ₂ O ₃ , and Ag ₂ O, thereby increasing the thickness of the electron depletion layer .

Despite the development of sensing materials using various types of nanostructures and the use of sensing materials that are bound to metal nanoparticle catalysts, it has been found that metal oxide semiconductors based on metal oxide semiconductors exhibit a level of sensitivity suitable for commercialization, The material has not been developed yet. In addition, it is urgent to develop an ultra-high-performance sensing material capable of selectively sensing an extremely small amount of bio-surface gas for a sensor based on a metal oxide semiconductor as a health care aerosol sensor.

Known methods for synthesizing nanostructures include nanowire growth using chemical vapor deposition, formation of nanostructure through physical vapor deposition, and chemical nanostructure growth by controlling the interface. However, these methods have problems in that mass production is not easy and troublesome process steps are involved, resulting in high process cost and long manufacturing time.

The nanoparticle catalysts have the greatest impact on sensitivity and selectivity. The gas sensor using the metal oxide semiconductor sensing material can maximize the effect of the catalyst when the catalyst is applied so as to be uniformly positioned on the surface of the sensing material as the sensing reaction occurs on the surface of the sensing material. However, the method of effectively binding the catalyst still requires research and development. This is because the catalyst nanoparticles aggregate easily during the manufacturing process of the sensor. It is important to create an open structure where gases can quickly diffuse into the inner layer of the sensing material.

In order to overcome the above-mentioned problems, there is a need for a nanostructure-based sensing material synthesis technology capable of uniformly binding a nanoparticle catalyst to the surface of a sensing material and easily manufacturing the same. It is required to develop a sensor capable of selectively sensing a very small amount of biomarker gas included in a commercially viable human body through the development of a simple and large-scale production of a sensing material.

Embodiments of the present invention are directed to a method of dispersing a nanoparticle catalyst in a first dispersion solution and a second dispersion solution in which a polymer and a metal oxide precursor are dissolved by using first and second dispersion solutions which are phase- Metal oxide precursor nanofiber in which the first dispersion solution is prepared by emulsion electrospinning of an emulsion state by using a surfactant in the form of fine droplets, The present invention also provides a method for producing porous metal oxide nanofibers in which nanoparticle catalysts are uniformly distributed on the surface by forming fine pores in metal oxide nanofibers and binding the catalyst to the surfaces of the fibers through the metal oxide nanofibers.

Particularly, it is possible to easily manufacture a large amount of sensing materials by the electrospinning method, and to provide a simple manufacturing technique which can uniformly carry out micropores and catalytic bindings without further processing including a catalyst during solution production. A simple step-by-step method in which nanoparticle catalysts are uniformly dispersed in the fine droplets formed by the first dispersion solution without aggregation and the catalysts can be uniformly distributed on the surface of the fibers through the heat treatment process This paper presents synthesis technology of oxide composite nanofiber sensing material which shows the effect of chemical sensitization or electronic increase and decrease catalysis on the bound catalyst particles and a gas sensor application technology using the same.

This is a method for solving the problems of the prior art, in which a sensing material is easily produced in the form of a nanostructure containing a large number of micropores, and at the same time, the nanoparticle catalysts are uniformly dispersed on the surface of the porous metal oxide nanofibers A gas sensor member capable of detecting a trace amount of gas, a gas sensor using the same, and a manufacturing method thereof.

According to an embodiment of the present invention, there is provided a method for preparing a porous metal oxide composite nanofiber, comprising: synthesizing a nanoparticle catalyst having a hydrophobic or hydrophilic functional group attached to a surface thereof; Dispersing the first dispersion solution using the synthesized nanoparticle catalyst; Dissolving at least one of the metal oxide precursor and the polymer in the second dispersion solution, and mixing the first dispersion solution and the second dispersion solution to each other so as to be phase-separated or layer-separated; Adding a surfactant to the mixed solution of the first dispersion solution and the second dispersion solution to prepare an emulsion solution for the first dispersion solution in a micro-droplet form; Preparing a composite nanofiber including at least one of the metal oxide precursor and the polymer by electrospinning the emulsion spinning solution, wherein the first dispersion solution is present in the form of a droplet in the form of a droplet; And a porous metal oxide composite in which the first dispersion solution is removed to form a plurality of micropores, and the nanoparticle catalyst is uniformly bound to at least one of the interior and the surface to functionalize the composite nanofiber, And a step of producing a nanofiber.

The step of synthesizing the nanoparticle catalyst may include synthesizing or functionalizing the nanoparticle catalyst so that the functional group serving as a stabilizer is attached to the surface of the nanoparticle catalyst to control the size of the nanoparticle catalyst, The nanoparticle catalyst may be dispersed in the first dispersion solution and not dispersed in the second dispersion solution.

Wherein the step of preparing the emulsion spinning solution comprises the steps of adding the surfactant to a solution obtained by mixing the first dispersion solution and the second dispersion solution and then finely pulverizing the fine particles of the first dispersion solution surrounded with the surfactant by using an ultrasonic pulverizer A micro-droplet may be formed to prepare an emulsion spinning solution.

The polymer is not soluble in the first dispersion solution but may be a polyurethane, a polyurethane copolymer, a cellulose acetate, a cellulose, an acetate butate, a cellulose derivative, a polymethylmethacrylate (PMMA), polymethyl acrylate (PMA), polyacrylic copolymer, polyvinylacetate copolymer, polyvinylacetate (PVAc), polyvinylpyrrolidone (PVP) (PPO), polystyrene (PS), polystyrene copolymer, polyethylene oxide (PEO), polypropylene oxide (PPO), polyethylene oxide copolymer, polypropylene oxide copolymer, polyvinyl alcohol (PC), polyvinyl chloride (PVC), polycaprolactone, polyvinyl fluoride, polyvinyl chloride Lee denpul fluoride may be composed of a copolymer, a polyamide, at least one of polyimide.

The step of preparing the porous metal oxide composite nanofibers may include a step of heat-treating the composite nanofibers at a temperature of 400 ° C to 900 ° C in an atmospheric or oxidized state.

In the step of preparing the porous metal oxide composite nanofibers, the micropore formed by removing the first dispersion solution as the content of the first dispersion solution increases may be formed into an elliptical shape having a long length.

The nanoparticle catalyst may have a concentration range of 0.01 to 7 wt% with respect to the porous metal oxide composite nanofiber.

The amount of the first dispersion solution contained in the emulsion spinning solution may be in the range of 1 vol% to 40 vol% based on the sum of the first dispersion solution and the second dispersion solution.

In the porous metal oxide composite nanofiber according to another embodiment of the present invention, a nanoparticle catalyst in which a hydrophobic or hydrophilic functional group is attached to a surface; Mixing a first dispersion solution dispersed using the nanoparticle catalyst and a second dispersion solution obtained by dissolving at least one metal oxide precursor and a polymer so as to be phase-separated or layer separated to add a surfactant, Forming a micro-droplet of the first dispersion solution to form an emulsion spinning solution, and electrospinning the emulsion spinning solution; And a plurality of micropores formed by removing fine droplets of the first dispersion solution from the composite nanofibers by heat treatment, wherein the nanoparticle catalyst is uniformly bound to at least one of the interior and the surface to perform functionalization ).

Here, the first dispersion solution may be composed of at least one of hexane, toluene, and mineral oil.

The second dispersion solution is subjected to layer separation or phase separation with the first dispersion solution and may be prepared by dissolving or dispersing in a solvent such as ethanol, water, chloroform, N, N'-dimethylformamide, dimethylsulfoxide, N, (N, N'-dimethylacetamide), N-methylpyrrolidone (N-methylpyrrolidone).

The emulsion spinning solution may be dispersed in the microdroplet form in the second dispersion solution while the first dispersion solution is surrounded by the surfactant.

The nanoparticle catalyst has a size in the range of 1 nm to 30 nm and is composed of Pt, Au, Ag, Pd, Pb, Ir, Rh, Fe, Cr, Zn, V, Sc, Ti, Cu, , W, Sn, in, Ta , Sb, Mn, Ga, Ge, Rh 2 O 3, MgO, TiO 2, V 2 O 5, ZnO, NiO, RuO 2, IrO 2, Co 3 O 4 at least one of ≪ / RTI >

The metal oxide _{precursor, SnO 2, ZnO, TiO 2} , Fe 2 O 3, WO 3, NiO, Co 3 O 4, V 2 O 5, Cr 2 O 3, Zn 2 SnO 4, SrTiFeO 3, CuO, SrTiO _{3, VO 2, VO, Ta} 2 O 5, Sb 2 O 3, Sc 2 O 3, Ga 2 O 3, GeO 2, Fe 3 O 4, CoO, CaO, In 2 O 3, MoO 3, MnO 2, Re ₂ O ₇ , PdO, LaCoO ₃ , NiCo ₂ O ₄ , Ca ₂ Mn ₃ O ₈ , ZrO ₂ , Al ₂ O ₃ , CeO ₂ , Pr ₆ O ₁₁ , Nd ₂ O ₃ , Sm ₂ O ₃ , Eu _{2 O 3, Gd 2 O 3,} Tb 4 O 7, Dy 2 O 3, Ho 2 O 3, Er 2 O 3, Yb 2 O 3, Lu 2 O 3, Ag 2 V 4 O 11, Ag 2 O, Li _{0 .03 La 0 .57 TiO 3,} LiV 3 O 8, RuO 2, IrO 2, MnO 2, InTaO 4, ITO, IZO, InTaO 4, MgO, CaCu 3 Ti 4 O 12, Ag 3 PO 4, BaTiO 3 , may be formed of a _{NiTiO 3, SrTiO 3, Sr 2} Nb 2 O 7, Sr 2 Ta 2 O 7, Ba 0 .5 Sr 0 .5 Co 0 .8 Fe 0 .2 O 3 -7 at least one of.

The nanoparticle catalyst may have a concentration range of 0.01 to 7 wt% with respect to the porous metal oxide composite nanofiber.

The amount of the first dispersion solution contained in the emulsion spinning solution may be in the range of 1 vol% to 40 vol% based on the sum of the first dispersion solution and the second dispersion solution.

The nanoparticle catalyst may be dispersed in the first dispersion solution and may not be dispersed in the second dispersion solution.

In the gas sensor according to another embodiment of the present invention, the porous metal oxide composite nanofibers described above and a gas sensor member having an electrode section for measuring a change in electrical conductivity, which is generated according to the concentration of a specific gas, The gas sensor member may include a nanorod structure formed by sputtering the emulsion spinning solution and containing the porous metal oxide composite nanofiber formed by heat treatment or by fracturing the porous metal oxide composite nanofiber have.

According to the present invention, a hydrophobic or hydrophilic nanoparticle catalyst is dispersed in a first dispersion solution, a polymer and a metal oxide precursor are dissolved and mixed with a first dispersion solution and a second dispersion solution in which phase separation or layer separation takes place, and a surfactant is added Nanofiber sensor material that has excellent sensitivity and selectivity by providing nanoparticle catalyst with electronic or chemical sensitization effect by synthesizing porous metal oxide composite nanofiber sensing material containing nanoparticle catalyst by electrospinning and heat treatment of the emulsion spinning solution thus prepared Can be produced. In addition, the micropores formed in the nanofiber formed by the first dispersion solution facilitates gas adsorption and forms a large surface area, thereby making it possible to manufacture a sensitive material having high sensitivity. In addition, it is possible to manufacture a structure capable of maximizing the effect of the catalyst by uniformly binding the nanoparticle catalyst dispersed therein to the surface of the metal oxide micropores while the first dispersion solution is removed.

In addition, by forming nanoparticle catalysts and metal oxide composites having various combinations, it is possible to provide a sensing material library capable of producing various kinds of yttria and having excellent selectivity. Porous metal oxide nanofibers containing such a nanoparticle catalyst can disclose a member for a gas sensor, a gas sensor, and a manufacturing method thereof, having excellent gas reaction characteristics through a large specific surface area due to maximized catalytic effect and formation of micropores .

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
1 is a flowchart showing a method of manufacturing a porous metal oxide composite nanofiber according to an embodiment of the present invention.
2 is a scanning electron micrograph of a porous WO ₃ nanofiber prepared according to an embodiment of the present invention.
3 is a transmission electron micrograph of nanoparticles according to an embodiment of the present invention.
4 is a view showing an emulsion spinning solution according to an embodiment of the present invention.
5 is a transmission electron micrograph of a nanofiber in which nanoparticles are uniformly bound according to an embodiment of the present invention.
6 is a view showing a result of the evaluation of characteristics of a gas sensor according to an embodiment of the present invention.
7 is a transmission electron micrograph of nanoparticles according to an embodiment of the present invention.
8 is a transmission electron micrograph of a nanofiber in which nanoparticles are uniformly bound according to an embodiment of the present invention.
9 is a view showing a result of the evaluation of characteristics of a gas sensor according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments will be described in detail below with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. The terms first, second, etc. may be used to describe various components, but the components are not limited by the terms, and the terms are used only for the purpose of distinguishing one component from another Is used.

Hereinafter, a nanoparticle catalyst having a functionalized porous metal oxide composite nanofiber structure synthesized by using an emulsion spinning solution in which a solution in which a nanoparticle catalyst is dispersed in a first dispersion solution and a second dispersion solution in which a polymer and a metal oxide precursor are dissolved is mixed A member for a gas sensor, a gas sensor and a manufacturing method thereof will be described in detail with reference to the accompanying drawings.

The present invention relates to a sensing material for a gas sensor, a gas sensor using the same and, more particularly, to a method for manufacturing a gas sensor using the same, which comprises mixing two different kinds of first dispersion solution and second dispersion solution, A spinning solution can be prepared. Here, the first dispersion solution may be dispersed in the nanoparticle catalyst, the second dispersion solution may be prepared by dissolving the metal oxide precursor and the polymer, and then mixing the first dispersion solution and the second dispersion solution to prepare an emulsion spinning solution. Then, the emulsion spinning solution is electrospun to form a metal oxide precursor / polymer composite nanofiber embedded in the first dispersion solution in a micro-droplet shape. Thereafter, the composite nanofibers are heat-treated to remove the polymer and oxidize the metal oxide precursor, whereby a number of micropores are formed in the process of removing the first dispersion solution, and a nanoparticle catalyst is formed on the micropored surface and / The porous metal oxide composite nanofiber can be easily produced by uniformly binding and functionalization. And a gas sensor can be manufactured using the same.

Examples of the present invention include synthesizing nanoparticle catalysts having a size ranging from 1 nm to 30 nm using oleylamine and preparing a solution in which catalyst-dispersed mineral oil or toluene and mineral oil are mixed, And a second dispersion solution in which the metal oxide precursor is dissolved, thereby preparing an emulsion spinning solution, using the same to produce a porous metal oxide sensing material uniformly bound with a nanoparticle catalyst, and utilizing the sensing material for a gas sensor .

In the present invention, a gas sensor member using a metal oxide semiconductor nanostructure in the prior art requires complicated and repetitive processes in its manufacturing process, and its gas sensing performance may vary greatly depending on the distribution of the catalyst, And it was required to improve the selectivity and sensitivity for selectively reacting with a specific fine gas among the gas having a complicated structure and also it was necessary to improve the reaction speed in order to grasp the gas detection result in real time, In order to improve the properties of the gas sensor using the oxide, a simple process is proposed to effectively bind the metal or metal oxide catalyst together with the improvement of the specific surface area. A nanoparticle catalyst is dispersed in fine droplets inside the emulsion to perform electrospinning to easily form fine pores inside the nanofiber, and at the same time, a size of 1 to 30 nm Of the nanoparticle catalyst was uniformly bound to the inside of the porous nanofiber to form a porous metal oxide composite nanofiber structure including a nanoparticle catalyst. Through this, it was possible to mass-synthesize the sensing material of the porous nanofiber structure in which the nanoparticle catalysts were uniformly bound.

Here, the porous metal oxide composite nanofibers in which the nanoparticle catalysts are uniformly bound to the metal oxide nanofibers can maximize the effect of the catalyst when the gases react with the sensing material by uniformly distributing the catalyst on the surface of the porous fiber, Since the micropores formed by the first dispersion solution increases the surface area and forms a gas permeable structure and can easily use various catalysts, it is possible to easily manufacture a sensing material exhibiting improved characteristics over the conventional semiconductor nanofibers It is expected to do. The gas sensor member, the gas sensor, and the manufacturing method thereof are realized by an efficient and easy process for manufacturing the gas sensor member having the characteristics as described above.

1 is a flowchart showing a method of manufacturing a porous metal oxide composite nanofiber according to an embodiment of the present invention.

Referring to FIG. 1, a method for preparing a porous metal oxide composite nanofiber includes: synthesizing a nanoparticle catalyst having a hydrophobic or hydrophilic functional group attached to a surface thereof; Dispersing the first dispersion solution using the synthesized nanoparticle catalyst; Dissolving at least one of the metal oxide precursor and the polymer in the second dispersion solution, and mixing the first dispersion solution and the second dispersion solution to each other so as to be phase-separated or layer-separated; Adding a surfactant to the mixed solution of the first dispersion solution and the second dispersion solution to prepare an emulsion solution for the first dispersion solution in a micro-droplet form; Preparing a composite nanofiber including at least one of the metal oxide precursor and the polymer by electrospinning the emulsion spinning solution, wherein the first dispersion solution is present in the form of a droplet in the form of a droplet; And a porous metal oxide composite in which the first dispersion solution is removed to form a plurality of micropores, and the nanoparticle catalyst is uniformly bound to at least one of the interior and the surface to functionalize the composite nanofiber, And a step of producing a nanofiber.

A first dispersion solution in which a nanoparticle catalyst is dispersed is prepared and the first dispersion solution in which the polymer and the metal oxide precursor are dissolved is mixed with a second dispersion solution which is separated or phase-separated and a surfactant is added to prepare an emulsion spinning solution The emulsion spinning solution is subjected to heat treatment after electrospinning to form micropores having long elliptical shapes formed by removing the first dispersion solution and fine pore formation such that the nanoparticle catalyst is uniformly dispersed on the surfaces of the micropores A porous nanofiber-shaped sensing material having a large surface area and uniformly distributed nanoparticle catalyst, and a method of manufacturing a member for a gas sensor using the same.

Hereinafter, a method of manufacturing a porous metal oxide composite nanofiber and a method of manufacturing a gas sensor will be described in detail with reference to FIG.

First, a nanoparticle catalyst can be synthesized in step S110.

A nanoparticle catalyst in which a hydrophobic or hydrophilic functional group is attached to the surface can be synthesized. When the functional group attached to the surface of the synthesized nanoparticle catalyst is hydrophobic, the nanoparticle catalyst can be dispersed in the first dispersion solution by crystallizing and dispersing a hydrophobic solvent such as oil in the first dispersion solution. Then, the aqueous solution may be selected as the second dispersion solution so that the nanoparticle catalyst is not dispersed in the second dispersion solution. In order to exhibit such characteristics, characteristics between the functional group and the first and second dispersion liquids can be selected so that the nanoparticle catalyst is dispersed only in the first dispersion solution. That is, the nanoparticle catalyst can be prepared so as not to be dispersed in the second dispersion solution while being dispersed in the first dispersion solution forming fine droplets on the emulsion spinning solution.

Here, as a stabilizer for controlling the size of the nanoparticle catalyst (or nanoparticle), a functional group such as polyvinylpyrrolidone (PVP) or oleylamine may be attached to the surface of the nanoparticle catalyst, A nanoparticle catalyst in which a functional group such as polyvinylpyrrolidone (PVP) or oleylamine is attached to the surface of the nanoparticle catalyst can be produced.

The nanoparticle catalyst is a nanoparticle having a size of 1 nm to 30 nm. As typical nanoparticle catalyst materials, for example, Pt, Au, Ag, Pd, Pb, Ir, Rh, Fe, Cr, Sc, Ti, Cu, Ni, Co, Ru, W, Sn, In, Ta, Sb, Mn, Ga, Ge, Rh 2 O 3, MgO, TiO 2, V 2 O 5, ZnO, NiO, RuO 2, IrO ₂ , and Co ₃ O ₄ , or a mixture of two or more of them. However, the material of the nanoparticle catalyst is not limited thereto, and if the nanoparticle catalyst mentioned above can be produced, it is not limited to the specific metals and oxides.

In step S120, the nanoparticle catalyst may be dispersed in the first dispersion solution.

The synthesized nanoparticle catalyst is dispersed in the first dispersion solution. The first dispersion solution is selected from a mixture of hexane, toluene, mineral oil, or a mixture of two or more. If the nanoparticle catalyst is a well-dispersed solvent, no specific solvent is limited. However, the first dispersion solution should be phase-separated or layer-separated from the second dispersion solution. And, the nanoparticle catalyst is not dispersed in the second dispersion solution, and when the first dispersion solution is mixed with the second dispersion solution, the nanoparticle catalyst should not migrate or coalesce into the second dispersion solution.

In step S130, an emulsion-type emulsion solution may be prepared by mixing the nanoparticle catalyst-dispersed first dispersion solution with the second dispersion solution in which the polymer and the metal oxide precursor are dissolved and the surfactant. After the electrospinning, nanoparticle catalyst nanoparticle catalyst dispersed in the nanoparticle may be formed. The nanoparticle catalyst may serve as a template for forming micropores and micropores having elliptical shapes.

First, a first dispersion solution in which the prepared nanoparticle catalyst is dispersed and a second dispersion solution in which layers are separated or phase-separated can be prepared.

The solvent of the second dispersion solution may be selected from the group consisting of ethanol, water, chloroform, N, N'-dimethylformamide, dimethylsulfoxide, N, N'-dimethylacetamide -dimethylacetamide, N-methylpyrrolidone, and a solvent capable of simultaneously dissolving the metal oxide precursor and the polymer should be selected.

In addition, the polymer which can be used here is not limited to a specific polymer if it is a polymer which can be dissolved together with a solvent and can be removed through a high-temperature heat treatment. Specific examples of the polymer include polyurethanes, polyurethane copolymers, cellulose acetate, cellulose, acetate butylate, cellulose derivatives, polymethyl methacrylate, methacrylate, PMMA), polymethyl acrylate (PMA), polyacrylic copolymer, polyvinylacetate copolymer, polyvinylacetate (PVAc), polyvinylpyrrolidone (PVP), polyvinyl alcohol (PEO), polypropylene oxide (PPO), polyethylene oxide copolymer, polypropylene oxide copolymer, polycarbonate (PPO), polystyrene (PS), polystyrene copolymer (PC), polyvinyl chloride (PVC), polycaprolactone, polyvinyl fluoride, polyvinylidene fluoride Ride is a copolymer, polyamide, or polyimide.

However, the polymer should not be dissolved in the first dispersion solution, and the first dispersion solution in which the nanoparticle catalyst is dispersed and the polymer that prevents the second dispersion solution from forming the emulsion state can not be used. In addition, the first and second dispersion solutions should be solutions characterized in that they are separated from each other by phase separation or layer separation.

The metal oxide precursor used in the second dispersion solution is not limited to a specific metal salt in the case of a precursor comprising a metal salt that is soluble in a solvent and forms a semiconductor metal oxide nanofiber that can be used as a gas sensor through high temperature heat treatment. A metal oxide precursor, SnO _2, ZnO, for example _{TiO 2, Fe 2 O 3,} WO 3, NiO, Co 3 O 4, V 2 O 5, Cr 2 O 3, Zn 2 SnO 4, SrTiFeO 3, CuO, _{SrTiO 3, VO 2, VO,} Ta 2 O 5, Sb 2 O 3, Sc 2 O 3, Ga 2 O 3, GeO 2, Fe 3 O 4, CoO, CaO, In 2 O 3, MoO 3, MnO 2 , Re ₂ O ₇ , PdO, LaCoO ₃ , NiCo ₂ O ₄ , Ca ₂ Mn ₃ O ₈ , ZrO ₂ , Al ₂ O ₃ , CeO ₂ , Pr ₆ O ₁₁ , Nd ₂ O ₃ , Sm ₂ O ₃ , Eu ₂ O ₃ , Gd ₂ O ₃ , Tb ₄ O ₇ , Dy ₂ O ₃ , Ho ₂ O ₃ , Er ₂ O ₃ , Yb ₂ O ₃ , Lu ₂ O ₃ , Ag ₂ V ₄ O ₁₁ , Ag ₂ O, Li _{0 .03} La _{0 .57} TiO ₃ , LiV ₃ O ₈ , RuO ₂ , IrO ₂ , MnO ₂ , InTaO ₄ , ITO, IZO, InTaO ₄ , MgO, CaCu ₃ Ti ₄ O ₁₂ , Ag ₃ PO ₄ , BaTiO _{3, NiTiO 3, SrTiO 3,} Sr 2 Nb 2 O 7, Sr 2 Ta 2 O 7, Ba 0 .5 and the like can be _{Sr 0 .5 Co 0 .8 Fe 0} .2 O 3 -7.

Next, the emulsion spinning solution can be prepared by mixing two different kinds of first dispersion solution and second dispersion solution which are separated or phase-separated from each other. Here, the first dispersion solution may be dispersed in the nanoparticle catalyst, the second dispersion solution may be prepared by dissolving the metal oxide precursor and the polymer, and then mixing the first dispersion solution and the second dispersion solution to prepare an emulsion spinning solution.

In addition, a surfactant may be added to the mixed solution of the first dispersion solution and the second dispersion solution to prepare an emulsion solution for use in which the first dispersion solution is present in a micro-droplet form. Generally, when layered or phase separated from each other, fine droplets are not formed as fine droplets with each other, but fine droplets can be formed by using a surfactant. For example, supposing that the first dispersion solution is an oil and the second dispersion solution is an aqueous solution, when a surfactant having a hydrophobic head and a hydrophilic tail is used, the hydrophobic head of the surfactant is attached to the periphery of the first dispersion solution, 2 Since the dispersion solution is directed, a fine first dispersion solution droplet can be formed in the mixed solution.

The first dispersion solution for forming the emulsion spinning solution preferably ranges from 1 vol% to 40 vol% based on the sum of the first dispersion solution and the second dispersion solution, and the nanoparticle catalyst contained in the first dispersion solution is It is preferable to have a concentration range of 0.01 to 7 wt% with respect to the finally produced metal oxide nanofibers.

The process of preparing the electrospinning solution in which the first dispersion solution forms fine droplets is performed by first dissolving the metal oxide precursor and the polymer in the solvent of the second dispersion solution and mixing the first dispersion solution containing the pre- To prepare a mixed solution so as to be separated or phase-separated. Thereafter, the surfactant is added to the first dispersion solution and the second dispersion solution which have undergone layer separation or phase separation and mixed thoroughly, and the mixture is pulverized for about 5 minutes using an ultrasonic pulverizer, and then stirred well using a magnetic bar. The agitation is preferably carried out at room temperature or below at 50 ° C and agitated sufficiently for 5 to 48 hours so that the fine droplets containing the nanoparticle catalyst and the metal oxide precursor and the polymer are uniformly mixed in the solution can do.

In step S140, the synthesized emulsion spinning solution is electrospun, and the metal oxide precursor / polymer composite nanofiber in which the fine droplets including the nanoparticle catalyst are uniformly dispersed through electrospinning can be produced.

Here, the second dispersion solution is evaporated during the electrospinning to form the composite nanofiber of the polymer and the metal oxide precursor, and the first dispersion solution in the state of fine droplets is trapped in the composite nanofiber of the polymer and the metal oxide precursor, In the form of fine droplets containing nanoparticle catalyst.

In the electrospinning method, a syringe is filled with the metal oxide precursor / polymer complex solution containing the metal organic structure having the nanoparticle catalyst prepared above, and then the syringe is pushed at a constant speed using a pump or the like So that a certain amount of the emulsion spraying liquid can be discharged.

The electrospinning system may be comprised of a DC source, a grounded conductive substrate, a syringe, a nozzle, applying a high voltage between about 5 kV and about 30 kV between the solution filled in the syringe and the conductive substrate to form an electric field, Electrospinning may also be performed so that the emulsion spinning solution discharged through the nozzle connected to the syringe due to the electric field is pulled out in the nanofiber form. The emulsion spinning solution in the form of a long burst can be obtained by evaporating and volatilizing the solvent of the second dispersion solution contained in the spinning solution, thereby obtaining solid polymer nanofibers. At the same time, a composite nanofiber in which fine droplets of the first dispersion solution containing the metal oxide precursor and the nanoparticle catalyst are dispersed can be produced. Herein, the discharge rate can be adjusted to within about 0.01 ml / min to about 0.5 ml / min, and precursor / polymer composite nanofibers containing fine droplets having a nanoparticle catalyst having a desired diameter can be controlled by controlling the voltage and the discharge amount. Can be manufactured.

Finally, in step S150, the first dispersion solution in which the nanoparticle catalysts are uniformly dispersed is removed through the high-temperature heat treatment of the composite nanofibers including the fine droplets dispersed in the nanoparticle catalyst, The porous metal oxide nanofibers can be produced in which fine pores are formed and at the same time, the nanoparticle catalyst is uniformly bound to functionalize the porous metal oxide composite nanofiber.

More specifically, the polymer and the metal oxide precursor composite nanofiber in which the first dispersion solution in which the nanoparticle catalyst is dispersed are present in the form of fine droplets are subjected to heat treatment to remove the polymer, oxidize the metal oxide precursor, And the nanoparticle catalyst dispersed in the first dispersion solution can be bound to the surface of the metal oxide. The heat treatment is carried out at a temperature of 400 ° C to 900 ° C in the atmospheric or oxidized state, and the space formed by the first dispersion solution micro-droplets during the heat treatment process forms a number of micropores similar to open pods . When the amount of the dispersion solution is small according to the content of the first dispersion solution, fine pores are formed in the interior, but the pore size is increased by elliptical pores and the size of nanotubes is conventionally formed. The nanoparticle catalyst dispersed in the first dispersion solution is uniformly bound to the formed pores.

Thus, the polymer and the first dispersion solution are decomposed and removed through the heat treatment, and at the same time, micropores are formed, the nanoparticle catalyst is bound, and the metal oxide precursor is oxidized to form the nanofiber, thereby forming the porous metal oxide composite nanofiber structure .

Then, the gas sensor can be manufactured using the porous metal oxide composite nanofiber.

After the porous metal oxide composite nanofibers containing the synthesized nanoparticle catalyst were dispersed in a solvent, the dispersion solution was applied to an alumina insulator substrate on which a sensor electrode (a parallel electrode capable of measuring electrical conductivity and electrical resistance change) was patterned Drop coating, spin coating, and the like. If the porous metal oxide composite nanofiber including the nanoparticle catalyst can be uniformly coated on the sensor substrate, the coating method is not particularly limited.

Also, in the sensor having the porous metal oxide composite structure including the synthesized nanoparticle catalyst, two or more kinds of composite sensing material array sensors having different nanoparticle catalysts and metal oxide sensing materials can be constituted.

The porous metal oxide composite nanofiber structure including the nanoparticle catalyst may have a diameter within a range of 100 nm to 2 μm, and the nanoparticle catalyst may have a size within a range of 1 nm to 30 nm . The nanoparticles are uniformly bound to the surface of the nanofibers, thereby maximizing the characteristics of the catalyst and maximizing the improvement of the characteristics of the detection material. The sensing material made by the above manufacturing method can be selected within a concentration range of 0.01 to 7 wt% of the nanoparticle catalyst relative to the metal oxide nanofiber, and it is possible to determine the presence or absence of the disease by sensing specific gases contained in the human exhalation In addition, indoor and outdoor harmful environmental gas can be detected.

As described above, the method of manufacturing the gas sensor member using the porous metal oxide composite nanofibers in which the nanoparticle catalyst is uniformly distributed while forming the micropores through the electrospinning technique of the emulsion spinning solution of the present invention, The reaction speed characteristics, the sensitivity characteristics, and the selectivity of the gas sensor can be greatly improved through the binding of the catalyst having uniformly dispersed chemical / electronic increase / decrease effect while forming a one-dimensional nanofiber structure having a wide surface area.

The porous metal oxide composite nanofiber and the gas sensor using the porous metal oxide composite nanofiber will be described below. Such a porous metal oxide composite nanofiber and a gas sensor using the porous metal oxide composite nanofiber can be explained in more detail by using the manufacturing method of the porous metal oxide composite nanofiber and the gas sensor manufacturing method described with reference to FIG. The method of manufacturing the porous metal oxide composite nanofiber and the gas sensor manufacturing method will not be described.

According to another embodiment of the present invention, the porous metal oxide composite nanofiber may include a nanoparticle catalyst, a composite nanofiber, and a plurality of micropores.

Nanoparticle catalysts may have hydrophobic or hydrophilic functional groups attached to their surfaces by the synthesis of catalysts and the like. The nanoparticle catalyst is preferably dispersed in the first dispersion solution and not dispersed in the second dispersion solution.

The nanoparticle catalyst has a size in the range of 1 nm to 30 nm and includes, for example, Pt, Au, Ag, Pd, Pb, Ir, Rh, Fe, Cr, Zn, V, Sc, Ti, Cu, Ru, W, Sn, in, Ta, Sb, Mn, Ga, Ge, Rh 2 O 3, MgO, TiO 2, V 2 O 5, ZnO, NiO, RuO 2, IrO 2, at least one of Co ₃ O ₄ Or more.

The composite nanofiber is a metal oxide precursor / polymer composite nanofiber, which is prepared by dispersing a first dispersion solution dispersed using a nanoparticle catalyst and a second dispersion solution obtained by dissolving at least one metal oxide precursor and a polymer in a phase separation or layer separation A surfactant is added thereto by mixing with each other to form a micro-droplet of the first dispersion solution surrounded by the surfactant to prepare an emulsion spinning solution. Then, the metal oxide precursor / polymer composite nanofiber may be formed by electrospinning the emulsion spinning solution.

Here, the first dispersion solution may be composed of at least one of, for example, hexane, toluene, and mineral oil. The second dispersion solution is subjected to layer separation or phase separation with the first dispersion solution and may be carried out in a solvent such as ethanol, water, chloroform, N, N'-dimethylformamide, dimethylsulfoxide, At least one of N, N'-dimethylacetamide, N-methylpyrrolidone, N, N'-dimethylacetamide and the like.

And the emulsion spinning solution can be dispersed in the form of micro-droplets in the second dispersion solution while the first dispersion solution is surrounded by the surfactant.

The metal oxide precursor may be selected from the group consisting of SnO ₂ , ZnO, TiO ₂ , Fe ₂ O ₃ , WO ₃ , NiO, Co ₃ O ₄ , V ₂ O ₅ , Cr ₂ O ₃ , Zn ₂ SnO ₄ , SrTiFeO ₃ , CuO _{, SrTiO 3, VO 2, VO} , Ta 2 O 5, Sb 2 O 3, Sc 2 O 3, Ga 2 O 3, GeO 2, Fe 3 O 4, CoO, CaO, In 2 O 3, MoO 3, MnO ₂ , Re ₂ O ₇ , PdO, LaCoO ₃ , NiCo ₂ O ₄ , Ca ₂ Mn ₃ O ₈ , ZrO ₂ , Al ₂ O ₃ , CeO ₂ , Pr ₆ O ₁₁ , Nd ₂ O ₃ , Sm ₂ O ₃ , Eu ₂ O ₃ , Gd ₂ O ₃ , Tb ₄ O ₇ , Dy ₂ O ₃ , Ho ₂ O ₃ , Er ₂ O ₃ , Yb ₂ O ₃ , Lu ₂ O ₃ , Ag ₂ V ₄ O ₁₁ , Ag ₂ O , Li _{0 .03} La _{0 .57} TiO ₃ , LiV ₃ O ₈ , RuO ₂ , IrO ₂ , MnO ₂ , InTaO ₄ , ITO, IZO, InTaO ₄ , MgO, CaCu ₃ Ti ₄ O ₁₂ , Ag ₃ PO ₄ , _{BaTiO 3, NiTiO 3, SrTiO 3} , Sr 2 Nb 2 O 7, Sr 2 Ta 2 O 7, Ba 0 .5 Sr 0 .5 Co 0 .8 Fe 0 .2 O 3 be made of at least one of _-7 have.

The plurality of micropores can be formed by removing fine droplets of the first dispersion solution from the composite nanofibers by heat treatment. The nanoparticle catalyst may be uniformly bound to at least one of the inner surface and the surface to functionize to form porous metal oxide composite nanofibers.

In this case, the nanoparticle catalyst may have a concentration range of 0.01 to 7 wt% with respect to the porous metal oxide composite nanofiber, and the amount of the first dispersion solution contained in the emulsion spinning solution may be in the range of 0.01 to 7 wt% To 1% by volume and 40% by volume.

As described above, according to the present invention, nanoparticles having a size of 1 to 30 nm dispersed in only one solution of two kinds of solutions in which phase separation or layer separation occurs are formed, and fine droplets dispersed in the formed nanoparticle catalyst are mixed with a metal oxide precursor / It is possible to provide a porous metal oxide composite nanofiber comprising a plurality of micropores produced by uniformly dispersing a nanoparticle catalyst on a surface and removing fine droplets by electrospinning with an emulsion solution present in an electrospinning solution and performing high temperature heat treatment have.

According to another embodiment of the present invention, there is provided a gas sensor comprising: the porous metal oxide composite nanofiber as described above; and a gas sensor member having an electrode part for measuring a change in electrical conductivity generated according to a concentration of a specific gas, The gas sensor member may include a nanorod structure in which the porous metal oxide composite nanofiber formed after the heat treatment by electrospinning the emulsion spraying liquid is formed or the porous metal oxide composite nanofiber is broken.

According to the present invention, it is possible to detect a gas having a very small amount of about 100 ppb by controlling the shape of the catalyst, which is an important factor in the characteristics of the gas sensor, by widening the surface area of the reaction, Discloses a gas sensor member, a gas sensor, and a manufacturing method thereof capable of mass production by simultaneously performing nanoparticle catalytic binding and nanofiber shape control processes by a simple process through electrospinning and heat treatment, .

Hereinafter, the present invention will be described in detail with reference to examples and comparative examples. The examples and comparative examples are merely intended to illustrate the present invention only, and the present invention is not limited to the following examples.

Example 1. Porous WO ₃ nanofiber shape control according to the content of the first dispersion solution

First, mineral oil may be selected as the first dispersion solution and water may be used as the second dispersion solution prior to carrying out the first embodiment. The polymer dissolved in the second dispersion solution may be PVP, and the tungsten precursor may be ammonium metatungstate hydrate.

It can be confirmed that the micropores of the nanofibers can be controlled by using the mixed emulsion solution of the first dispersion solution and the second dispersion solution without dispersing the nanoparticle catalyst in the first dispersion solution.

After adding 0.4 g of ammonium metatungstate hydrate and 0.5 g of PVP to 3.5 ml of water, the mixture can be stirred at room temperature and 500 rpm for 6 hours using a magnetic bar. A solution in which 0.1, 0.2, 0.3, 1, and 1.5 ml of mineral oil are added to a solution which is completely dissolved by stirring and becomes clear, respectively, can be prepared. Triton-X was added as a surfactant to the five solutions and pulverized for about 5 minutes using an ultrasonic grinder to prepare a solution containing oil droplets. Thereafter, the solution can be stirred again at 500 rpm for about 1 hour. It was confirmed that milk was similar to milky white turbid solution.

)에 담고 펌프에 연결하여 10 μl/분의 토출 속도로 전기방사 용액을 밀어내고, 방사할 때 사용되는 노즐(needle, 23 gauge)과 나노섬유가 모이는 집전체 사이의 전압을 10 kV로 하여 전기방사를 진행할 수 있다. 나노섬유의 집전판으로는 SUS(stainless use steel)를 사용할 수 있고, 노즐과 집전체 사이의 거리는 15 cm로 설정할 수 있다. 제조된 고분자/전구체 및 오일 미세방울 복합 나노섬유는 대기 상태에서 승온 속도 10 °C/분으로 700 °C까지 올린 후, 1시간 유지시켜 오일 및 고분자를 제거하고 텅스텐 산화물로 제조할 수 있다.The prepared solution can be prepared as nanofibers by electrospinning. The prepared electrospinning solution was injected into a syringe (Henke-Sass Wolf, 10 mL NORM-JECT

) And connected to the pump. The electrospinning solution was pushed out at a discharge rate of 10 μl / min. The voltage between the needle (23 gauge) used for spinning and the collector where the nanofibers were collected was set to 10 kV, Radiation can proceed. Stainless steel (SUS) can be used as the collector plate of the nanofiber, and the distance between the nozzle and the collector can be set to 15 cm. The prepared polymer / precursor and oil microbubble composite nanofibers can be prepared from tungsten oxide by raising the temperature to 700 ° C at a heating rate of 10 ° C / min in an atmospheric state and then keeping it for 1 hour to remove oil and polymer.

2 is a scanning electron micrograph of a porous WO ₃ nanofiber prepared according to an embodiment of the present invention.

Referring to FIG. 2, one-dimensional nanofibers are formed. The micropores formed according to the content of the mineral oil (first dispersion solution) according to Example 1 are elongated in an elongated elliptical shape, Can be seen to have a long elliptical shape. The diameter of the prepared nanofibers is 200 to 500 nm.

Example 2. Fabrication of porous WO ₃ nanofibers with Ni nanoparticle catalyst

First, mineral oil and water may be used for the first dispersion solution and the second dispersion solution, respectively.

In Example 2, a nanoparticle synthesis method using oleylamine can be used to synthesize a Ni nanoparticle catalyst well dispersed in mineral oil. Nickel (II) acetylacetonate can be used as a precursor of Ni and oleylamine as a solvent.

1 mmol of nickel acetylacetonate was placed in 20 ml of oleylamine and heated to 300 ° C at a rate of 5 ° C / min. After cooling for 1 hour, the nanoparticles were cooled to room temperature . The synthesized Ni nanoparticles can be removed with 80 ml of ethanol by using a centrifuge. Here, it is preferable that the centrifuge is centrifuged at 3,000 rpm for 10 minutes or more. After the ethanol washing and centrifugation processes are carried out three or more times, the Ni nanoparticles can be collected.

3 is a transmission electron micrograph of nanoparticles according to an embodiment of the present invention.

Referring to FIG. 3, a transmission electron microscope image of Ni nanoparticles prepared using oleylamine according to Example 2 shows that the synthesized nanoparticle catalyst has a diameter of about 10 nm.

The nanoparticles thus synthesized can be dispersed in mineral oil, which is the first dispersion solution. To prepare the second dispersion solution, 0.4 g of ammonium metatungstate hydrate and 0.5 g of PVP were added to 3.5 ml of water, 0.1 ml of the mineral oil in which the Ni nanoparticles were dispersed was added, and the mixture was stirred at 500 rpm The mixture can be stirred for 6 hours using a magnetic bar. Thereafter, triton-X is added as a surfactant and pulverized using an ultrasonic grinder for about 5 minutes, whereby a solution containing oil droplets in which Ni nanoparticles are dispersed can be prepared. The solution may then be stirred again at 500 rpm for about 1 hour.

4 is a view showing an emulsion spinning solution according to an embodiment of the present invention.

Referring to FIG. 4, a mixed emulsion spinning solution using mineral oil in which Ni nanoparticles are dispersed and water in which PVP and tungsten precursor are dissolved according to Example 2 can be confirmed. 4 (a) is a photograph before the surfactant is introduced, and it can be seen that the mineral oil (first dispersion solution) as the first dispersion solution and the aqueous solution of the polymer / tungsten precursor mixture as the second dispersion solution are separated. Fig. 4 (b) shows that the solution was shaken using an ultrasonic grinder without a surfactant, indicating that the solution was still separated. FIG. 4 (c) shows that the solution was emulsified with the surfactant triton-X to form a fine droplet, resulting in a gray turbid solution.

)에 담고 펌프에 연결하여 10 μl/분의 토출 속도로 전기방사 용액을 밀어내고, 방사할 때 사용되는 노즐(needle, 23 gauge)과 나노섬유가 모이는 집전체 사이의 전압을 10 kV로 하여 전기방사를 진행할 수 있다. 나노섬유의 집전판으로는 SUS(stainless use steel)를 사용하고, 노즐과 집전체 사이의 거리는 15 cm로 설정할 수 있다. 제조된 고분자/전구체 및 오일 미세방울 복합 나노섬유는 대기 상태에서 승온 속도 분당 °C로 700 °C까지 올린 후 1시간 유지시켜 오일 및 고분자를 제거하고 Ni 나노입자가 결착된 텅스텐 산화물로 제조할 수 있다.Mixed emulsion spinning solutions made of grayish turbid liquids due to Ni nanoparticles can be made from nanofibers through electrospinning. The prepared electrospinning solution was injected into a syringe (Henke-Sass Wolf, 10 mL NORM-JECT

) And connected to the pump. The electrospinning solution was pushed out at a discharge rate of 10 μl / min. The voltage between the needle (23 gauge) used for spinning and the collector where the nanofibers were collected was set to 10 kV, Radiation can proceed. SUS (stainless use steel) is used as the collector plate of the nanofiber, and the distance between the nozzle and the collector can be set to 15 cm. The prepared polymer / precursor and oil microbubble composite nanofibers can be prepared from tungsten oxide bound to Ni nanoparticles by removing oil and polymer by keeping the temperature at 700 ° C / min. have.

5 is a transmission electron micrograph of a nanofiber in which nanoparticles are uniformly bound according to an embodiment of the present invention.

Referring to FIG. 5, after heat treatment according to Example 2, transmission electron microscope photographs and EDS (Energy Dispersive Spectrometer) of nanofibers in which elliptical micropores having a long length due to mineral oil were formed and Ni nanoparticles were uniformly bound, ) Analysis results. FIG. 5 (a) is a transmission electron micrograph of porous WO ₃ nanofibers to which Ni nanoparticles are bonded after heat treatment, wherein large pores such as pods are formed in the nanofiber, and porous nano- It can be confirmed that the fibers are synthesized. FIG. 5 (b) is a transmission electron micrograph showing a high magnification, and it can be confirmed that the WO ₃ nanofibers having a monoclinic phase having the (112) plane and the (200) plane were formed. FIG. 5 (c) shows that Ni is uniformly distributed in the nanofiber as a result of the EDS analysis.

COMPARATIVE EXAMPLE 1. Preparation of pure WO ₃ nanofibers without nanoparticle catalyst binding and without emulsion electrospinning to form pores

Comparative Example 1 is a comparative example as compared with Example 2, except that the nanoparticle catalyst was not bound and emulsion electrospinning was not performed, so pure WO ₃ Nanofiber. ≪ / RTI > More specifically, 0.5 g of PVP and 0.4 g of ammonium metatungstate hydrate, a precursor of tungsten oxide, can be agitated at 3.5 rpm in DI water at 500 rpm for 5 hours at room temperature. After stirring all, the tungsten oxide precursor / polymer mixed solution is placed in an electric syringe and connected to a syringe pump to push the solution at a discharge rate of 0.1 ml / min. The nozzle used in the electrospinning was a 23 gauge, and the distance between the needle and the current collector for obtaining the nanofibers was about 15 cm, and a voltage of 10 kV was applied to manufacture a tungsten oxide precursor / polymer composite nanofiber web can do. The prepared tungsten oxide precursor / polymer composite nanofiber is subjected to high temperature heat treatment to remove the polymer, and the tungsten oxide precursor can be oxidized to form WO ₃ . Here, the high temperature heat treatment is performed at 700 ° C for 1 hour, and the temperature increase rate is kept constant at 10 ° C / min.

The pure WO ₃ nanofibers prepared in Comparative Example 1 can be used to compare the sensing characteristics of multiple gases with the WO ₃ nanofibers prepared in Example 2 described above.

Experimental Example 1. Preparation and characterization of a gas sensor using porous WO ₃ nanofibers prepared by emulsion electrospinning uniformly bound to a Ni nanoparticle catalyst and pure WO ₃ nanofibers prepared by simple electrospinning

5 mg of each nanofiber was dispersed in 100 μl of ethanol in order to prepare the sensing material for the gas sensor manufactured in Example 2 and Comparative Example 1 by an expiration sensor and then pulverized through ultrasonic washing for 1 hour have. A nanorod structure in which the nanofiber structure synthesized in the pulverization process is further shortened in the longitudinal direction may be exhibited.

The prepared solution can be coated on a 3 mm × 3 mm alumina substrate having two parallel gold (Au) electrodes spaced 300 μm apart by a drop coating method. In the coating process, the mixed solution dispersed in the prepared ethanol may be coated on an alumina substrate having a sensor electrode portion using a micropipette, and then dried on a 60 ° C hot plate. This process can be repeated 4-6 times to allow a sufficient amount of material to be coated on top of the alumina sensor substrate.

In addition, the gas sensor manufactured to evaluate the characteristics of the expiratory flow sensor has a concentration of hydrogen sulfide (H ₂ S) gas, which is a biomarker gas for the diagnosis of bad breath, at a relative humidity (90% RH) similar to the humidity of the gas 5, 4, 3, 2, and 1 ppm, while maintaining the sensor operating temperature at 250 ° C.

In Experimental Example 1, not only hydrogen sulfide (H ₂ S), which is a representative example of volatile organic compound gas used as a biomarker of disease but also acetone (CH ₃ COCH ₃ ), which is an indicator gas for diabetes diagnosis, bad breath diagnosis and lung cancer diagnosis, (C ₆ H ₅ CH ₃ ), ammonia (NH ₃ ) gas which is a biomarker of kidney disease, and ethanol (C ₂ H ₅ OH), carbon monoxide (CO) and pentane (nC ₅ H ₁₂ ) Selective gas sensing characteristics can be evaluated.

6 is a view showing a result of the evaluation of characteristics of a gas sensor according to an embodiment of the present invention.

Referring to FIG. 6, it was confirmed that as Experimental Example 1, the porous WO ₃ nanofiber prepared by emulsion electrospinning uniformly bound Ni nanoparticle catalyst according to Example 2 and the humidity of pure WO ₃ nanofiber according to Comparative Example 1 (C ₆ H ₅ CH ₃ ), acetone (CH ₃ COCH ₃ ), ammonia (NH ₃ ), hydrogen sulphide (NH ₃ ) and hydrogen sulfide H ₂ S), ethanol (C ₂ H ₅ OH), carbon monoxide (CO) and pentane (nC ₅ H ₁₂ ).

6 (a) shows the degree of reaction (R _air / R _{gas ,} where R _air is the concentration of the metal oxide material when air is injected) when the concentration of the hydrogen sulfide gas decreases to 5, 4, 3, Resistance value, and R _gas is the resistance value of the metal oxide material when the toluene gas is injected). It can be seen that micropores are formed through the emulsion electrospinning proposed in the present invention and WO ₃ nanofibers uniformly bound to Ni nanoparticles show about 10 times higher reaction characteristics than pure WO ₃ nanofibers.

FIG. 6 (b) shows the formation of micropores through emulsion electrospinning at 250 ° C. and the use of WO ₃ nanofibers uniformly bound to Ni nanoparticles and pure WO ₃ nanofibers to produce hydrogen sulfide The reactivity values at 1 ppm of concentration are shown for acetone, toluene, ethanol, carbon monoxide, pentane, and ammonia gas, which are biomarkers of other diseases. It was confirmed that the selective detection characteristics of hydrogen sulfide, which is a biological indicator gas of halitosis, are remarkably improved in comparison with acetone, ammonia, toluene, ethanol, carbon monoxide and pentane gas, which are biological indicators of other diseases.

Example 3. Preparation of porous WO ₃ nanofibers with Pd nanoparticle catalyst bound

First, a mixed solution of mineral oil and toluene may be used as the first dispersion solution, and water may be used as the second dispersion solution.

In order to synthesize a Pd nanoparticle catalyst well dispersed in mineral oil and toluene, a nanoparticle synthesis method using oleylamine can be used in the same manner as in Example 2. [

Palladium acetylacetonate can be used as a precursor of Pd and oleylamine as a solvent. 1 mmol of palladium acetylacetonate was placed in 20 ml of oleylamine and heated to 300 ° C at a rate of 5 ° C per minute and maintained for 1 hour and then cooled to room temperature to form nanoparticles . The synthesized Pd nanoparticles can be removed by adding 80 ml of ethanol and using a centrifuge. Here, it is preferable that the centrifuge is centrifuged at 3,000 rpm for 10 minutes or more. After the ethanol washing and centrifugation process is performed three more times, the Pd nanoparticles can be dispersed in toluene and stored.

7 is a transmission electron micrograph of nanoparticles according to an embodiment of the present invention.

Referring to FIG. 7, it can be confirmed that the nanoparticle catalyst synthesized through the transmission electron microscope photograph of the Pd nanoparticles produced by the above process has a diameter of about 7 nm.

The nanoparticles synthesized by the above process and dispersed in toluene can be dispersed by mixing with mineral oil. When only toluene is used as the first dispersion solution, a large amount of fine droplets is not left in the nanofiber due to the evaporation of toluene during electrospinning, so that a large amount of fine droplets can be present by mixing with mineral oil. To prepare the second dispersion solution, 0.4 g of ammonium metatungstate hydrate and 0.5 g of PVP were added to 3.5 ml of water, and then 1.5 ml of toluene and mineral oil mixed solution containing Pd nanoparticles dispersed And the mixture is stirred at room temperature for 6 hours at 500 rpm using a magnetic bar. The two solutions thus prepared are respectively pulverized for about 5 minutes by adding triton-X as a surfactant and using an ultrasonic grinder to prepare a solution containing fine droplets in which Pd nanoparticles are dispersed. Thereafter, the solution can be stirred again at 500 rpm for about 1 hour.

)에 담고 펌프에 연결하여 10 μl/분의 토출 속도로 전기방사 용액을 밀어내고, 방사할 때 사용되는 노즐(needle, 23 gauge)과 나노섬유가 모이는 집전체 사이의 전압을 10 kV로 하여 전기방사를 진행할 수 있다. 나노섬유의 집전판으로는 SUS(stainless use steel)를 사용하고, 노즐과 집전체 사이의 거리는 15 cm로 설정할 수 있다. 제조된 고분자/전구체 및 오일 미세방울 복합 나노섬유는 대기 상태에서 승온 속도 분당 °C로 700 °C까지 올린 후 1시간 유지시켜 톨루엔, 오일 및 고분자를 제거하고 Pd 나노입자가 결착된 텅스텐 산화물로 제조할 수 있다.Two mixed emulsion spinning solutions made from a grayish turbid solution due to Pd nanoparticles can be fabricated from nanofibers through electrospinning. The prepared electrospinning solution was injected into a syringe (Henke-Sass Wolf, 10 mL NORM-JECT

) And connected to the pump. The electrospinning solution was pushed out at a discharge rate of 10 μl / min. The voltage between the needle (23 gauge) used for spinning and the collector where the nanofibers were collected was set to 10 kV, Radiation can proceed. SUS (stainless use steel) is used as the collector plate of the nanofiber, and the distance between the nozzle and the collector can be set to 15 cm. The prepared polymer / precursor and oil microbubble composite nanofibers were heated to 700 ° C per minute at a rate of temperature rise in the atmospheric state and maintained for 1 hour to remove toluene, oil and polymer, and made of tungsten oxide with Pd nanoparticles bound thereto can do.

8 is a transmission electron micrograph of a nanofiber in which nanoparticles are uniformly bound according to an embodiment of the present invention.

Referring to FIG. 8, a transmission electron microscope photograph and an EDS (Energy Dispersive Spectrometer) analysis result of a nanofiber in which a tube shape is formed due to mineral oil and Pd nanoparticles are uniformly bound can be shown. In Example 3, since the content of the first dispersion solution was increased by 10 times as compared with Example 2, the nanofibers contained an excessive amount of fine droplets, and thus could form nanotubes.

FIG. 8 (a) shows a transmission electron microscope photograph of the porous WO ₃ nanofibers to which Pd nanoparticles are bonded after the heat treatment, and it can be seen that the nanofibers have a tube shape. FIG. 8 (b) shows a transmission electron microscope image at a high magnification, confirming the (200) plane of the monoclinic nanofibers and confirming formation of WO ₃ nanofibers. 8 (c) shows that Pd is uniformly distributed within the nanotube fibers as a result of EDS analysis.

Experimental Example 2. Fabrication and characterization of a gas sensor using porous WO ₃ nanofibers prepared by emulsion electrospinning in which Pd nanoparticle catalysts were uniformly bound and pure WO ₃ nanofibers prepared by simple electrospinning

5 mg of each nanofiber may be dispersed in 100 μl of ethanol to prepare a sensing material for a gas sensor manufactured in Example 3 and Comparative Example 1, followed by ultrasonic washing for 1 hour. A nanorod structure in which the nanofiber structure synthesized in the pulverization process is further shortened in the longitudinal direction may be exhibited.

The prepared solution can be coated on a 3 mm × 3 mm alumina substrate having two parallel gold (Au) electrodes spaced 300 μm apart by a drop coating method. In the coating process, the mixed solution dispersed in the prepared ethanol is applied on an alumina substrate having a sensor electrode portion using a micropipette, and then dried on a hot plate at 60 ° C. This process can be repeated 4-6 times to allow a sufficient amount of material to be coated on top of the alumina sensor substrate.

In addition, the gas sensor manufactured for the evaluation of the characteristics of the expiratory flow sensor measures the concentration of toluene gas, which is a biomarker gas for diagnosis of lung cancer, at the relative humidity (90% RH) similar to the humidity of the gas coming from the mouth of a person, , 2, and 1 ppm, while the sensor operating temperature is maintained at 350 ° C and the response characteristics to gas can be evaluated.

9 is a view showing a result of the evaluation of characteristics of a gas sensor according to an embodiment of the present invention.

Referring to FIG. 9, there are shown, as Experimental Example 2, porous WO ₃ nanotube fibers prepared by emulsion electrospinning in which a Pd nanoparticle catalyst according to Example 3 is uniformly bound and pure WO ₃ nanofibers according to Comparative Example 1 (1-5 ppm) at a humidity condition of 90% RH and a temperature condition of 350 ° C. (R _air / R _{gas ,} where R _air means the resistance value of the metal oxide material when air is injected, and R _gas represents the resistance value of the metal oxide material when the toluene gas is injected).

It can be seen that micropores are formed through the emulsion electrospinning proposed in the present invention and WO ₃ nanofibers uniformly bound with Pd nanoparticles exhibit reaction characteristics about 10 times higher than those of pure WO ₃ nanofibers.

The above examples show the characteristics of the WO ₃ nanofiber material having micropores formed by emulsion electrospinning in which Ni and Pd nanoparticle catalysts having high sensitivity and selectivity for hydrogen sulfide and toluene are uniformly bound. By differentiating the nanoparticle catalysts and metal oxides, one can expect to manufacture sensors with high sensitivity and selectivity for other gases. Also, selectivity change characteristics can be expected according to the change of the combination of the catalyst and the metal oxide. Thus, a nanosensor array having high sensitivity and high selectivity can be manufactured using various kinds of nanofibers that are bound with various kinds of nanoparticle catalyst particles. The porous metal oxide composite nanofiber sensing material in which the catalyst is uniformly bound can be used as an excellent harmful environmental gas sensor and a gas sensor for health care for analysis and diagnosis of exhalation volatile organic compound gas.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments described in the present invention are not intended to limit the technical spirit of the present invention but to illustrate the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

Claims (18)

Synthesizing a nanoparticle catalyst in which a hydrophobic or hydrophilic functional group is attached to the surface;
Dispersing the first dispersion solution using the synthesized nanoparticle catalyst;
Dissolving at least one of a metal oxide precursor and a polymer in a second dispersion solution, mixing the first dispersion solution and the second dispersion solution so as to be phase-separated or layer-separated, -droplet) in the form of an emulsion;
Preparing a composite nanofiber including at least one of the metal oxide precursor and the polymer by electrospinning the emulsion spinning solution, wherein the first dispersion solution is present in the form of a droplet in the form of a droplet; And
Wherein the nanoparticle catalyst is uniformly bound to at least one of the inside and the surface to functionize the porous metal oxide composite nano- Steps to fabricate fiber
The method of claim 1, The method according to claim 1,
Wherein synthesizing the nanoparticle catalyst comprises:
Wherein the nanoparticle catalyst is synthesized or surface-treated so as to adhere to the surface of the nanoparticle catalyst in order to control the size of the nanoparticle catalyst, the nanoparticle catalyst being dispersed in the first dispersion solution Wherein the porous metal oxide nanofibers are not dispersed in the second dispersion solution. The method according to claim 1,
The step of producing the emulsion spinning solution comprises:
A surfactant is added to a solution obtained by mixing the first dispersion solution and the second dispersion solution and a micro-droplet of the first dispersion solution surrounded by the surfactant is formed by using an ultrasonic pulverizer to form an emulsion chamber Wherein the porous metal oxide composite nanofiber is produced by using the porous metal oxide composite nanofiber. The method according to claim 1,
The polymer may be,
And is not soluble in the first dispersion solution, and may be selected from the group consisting of polyurethanes, polyurethane copolymers, cellulose acetate, cellulose, acetate butylate, cellulose derivatives, polymethyl methacrylate, methacrylate, PMMA), polymethyl acrylate (PMA), polyacrylic copolymer, polyvinylacetate copolymer, polyvinylacetate (PVAc), polyvinylpyrrolidone (PVP), polyvinyl alcohol (PEO), polypropylene oxide (PPO), polyethylene oxide copolymer, polypropylene oxide copolymer, polycarbonate (PPO), polystyrene (PS), polystyrene copolymer (PC), polyvinyl chloride (PVC), polycaprolactone, polyvinyl fluoride, polyvinylidene fluoride DE copolymer, polyamide, method for producing a porous metal oxide composite nanofibers, characterized in that consisting of at least one of polyimide. The method according to claim 1,
The step of preparing the porous metal oxide composite nanofiber may include:
Treating the composite nanofiber at a temperature of 400 ° C to 900 ° C in an atmospheric or oxidized state. The method according to claim 1,
The step of preparing the porous metal oxide composite nanofiber may include:
Wherein the plurality of micropores formed by removing the first dispersion solution form an elongated elliptical shape as the content of the first dispersion solution increases. The method according to claim 1,
Wherein the nanoparticle catalyst has a concentration range of 0.01 to 7 wt% with respect to the porous metal oxide composite nanofiber. The method according to claim 1,
Wherein the amount of the first dispersion solution contained in the emulsion spinning solution is in the range of 1 vol% to 40 vol% based on the sum of the first dispersion solution and the second dispersion solution. Gt; delete delete delete delete delete delete delete delete delete delete

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