KR20200034432A - graphene quantum dots-semiconducting oxide-carbon nanofiber composite photocatalyst electrode manufacturing method - Google Patents
graphene quantum dots-semiconducting oxide-carbon nanofiber composite photocatalyst electrode manufacturing method Download PDFInfo
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Abstract
Description
본 발명은 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매 전극 제조방법에 관한 것으로, 보다 구체적으로는 가시광선 영역의 실내용 인공광원에서 높은 광촉매 활성을 갖는 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber)로 이루어진 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매 제조방법에 관한 것이다.The present invention relates to a method for manufacturing a graphene quantum dot-oxide semiconductor-carbon nanofiber composite photocatalyst electrode, and more specifically, graphene quantum dots (GQDs) having high photocatalytic activity in indoor artificial light sources in the visible region. -Semiconducting oxide (semiconducting oxide)-carbon nanofiber (carbon nanofiber) consisting of a graphene quantum dot-oxide semiconductor-relates to a method for producing a carbon nanofiber composite photocatalyst.
일반적으로 광촉매는 "빛을 조사하였을 때 자신의 상태는 그대로 유지한 채 반응 속도를 빠르게 하거나 느리게 하는 물질"로서, ZnO, WO3, SnO2, ZrO2, TiO2, CdS 등과 같은 반도체성 금속 산화물이나 황 화합물이 이용된다.In general, a photocatalyst is a substance that accelerates or slows the reaction rate while maintaining its state when irradiated with light. As a result, semiconductor metal oxides or sulfur compounds such as ZnO, WO3, SnO2, ZrO2, TiO2, CdS, etc. Is used.
광촉매 소재로 활용되기 위해서는 다음과 같은 조건을 만족시켜야 한다. (1)광촉매는 광학적으로 활성이 있으면서도 광부식이 없는 물질이어야 한다. (2)빛 외에는 반응하지 않는 물질로 내구성이 뛰어나고 화학적, 생물학적으로 비활성인 물질이 유리하다. (3)가시광선이나 자외선 영역의 빛 등 다양한 종류의 빛을 이용할 수 있는 물질이어야 한다.In order to be used as a photocatalyst material, the following conditions must be satisfied. (1) The photocatalyst should be a material that is optically active and has no photocorrosion. (2) As a material that does not react except for light, a material having excellent durability and chemically and biologically inactive is advantageous. (3) It should be a material that can use various types of light, such as visible light or ultraviolet light.
위의 조건을 고려해보았을 때 광촉매로써 가장 적합한 물질로 현재 티타늄디옥사이드(titanium dioxide, TiO2)가 가장 많이 상용되고 있다.Considering the above conditions, titanium dioxide (TiO2) is the most commonly used material as a photocatalyst.
티타늄디옥사이드(titanium dioxide, TiO2)는 온도에 따라 다른 결정 구조를 가지며, 일반적으로 루틸(rutile)과 아나타제(anatase) 형태로 존재한다.Titanium dioxide (Titanium dioxide, TiO2) has a different crystal structure depending on the temperature, and is generally present in the form of rutile and anatase.
티타늄디옥사이드(titanium dioxide, TiO2), 아나타제(anatase), 루틸(rutile) 모두 광촉매이다. 티타늄디옥사이드(titanium dioxide, TiO2), 루틸(rutile)에서 가시광 영역에서는 효율이 낮아 티타늄디옥사이드(titanium dioxide, TiO2) 광촉매에서 아나타제(anatase)가 루틸(rutile)에 비해 상대적으로 (1)작은 유효질량에 따른 높은 전하 이동도, (2)작은 결정립 크기, (3)긴 전하 수명, (4)높은 전도대 바닥(conduction band bottom) 위치 등의 장점을 가지고 있어 자외선 광원에서 높은 광촉매 활성 효과를 나타낸다고 알려져 있다.Titanium dioxide (TiO2), anatase, and rutile are all photocatalysts. In titanium dioxide (TiO2) and rutile, the efficiency is low in the visible light region, so in the titanium dioxide (TiO2) photocatalyst, anatase (1) has a relatively small effective mass compared to rutile. It is known to exhibit high photocatalytic activity in ultraviolet light sources due to its advantages such as high charge mobility, (2) small grain size, (3) long charge life, and (4) high conduction band bottom position.
현재 티타늄디옥사이드(titanium dioxide, TiO2)의 광촉매 효율은 티타늄디옥사이드(titanium dioxide, TiO2) 분말의 종류 및 입도, 분해물질, 조건 등에 따라 달라지기 때문에 객관적인 비교수치는 나와 있지 않으며, 단지 루틸(rutile) (Eg=3.0 eV)보다 더 많은 자외선 영역의 에너지를 흡수할 수 있는 아나타제(anatase) (Eg=3.2 eV)가 광촉매 활성이 높은 것으로 나타나 있을 뿐이다. 그러나 두 상이 혼합된 경우에는 아직 확립된 결과가 나오지 않은 상태이다. 많은 연구자들의 연구에 따라 100% 아나타제(anatase) 보다는 루틸(rutile)이 섞인 것이 효율이 좋다는 연구(P25-graphene composite as a high performance photocatalyst, Hao Zhang, et al., ACS Nano 4 (2010) 380-386.)가 보고되었으며, 루틸(rutile)을 단독으로 사용하였을 때에도 광촉매 효과가 나타나는 것을 보여주는 연구 결과 (TiO2 광촉매 활성에서 rutile 구조의 영향, 김승민, 윤태관, 홍대일, Journal of the Korean Chemical Society, 49 (6) (2005) 567-574)도 있다. 현재 가장 광분해 효율이 좋다고 알려진 티타늄디옥사이드(titanium dioxide, TiO2)는 Degussa사의 P-25 라는 제품으로, 70% 아나타제(anatase)와 30% 루틸(rutile)이 섞인 혼합상의 형태이다.Currently, the photocatalytic efficiency of titanium dioxide (Titanium dioxide, TiO2) varies depending on the type and particle size of the titanium dioxide (Titanium dioxide (TiO2) powder, decomposition products, conditions, etc., so there is no objective comparison value, only rutile (rutile) ( It is only shown that anatase (Eg = 3.2 eV), which can absorb more energy in the ultraviolet region than Eg = 3.0 eV), has high photocatalytic activity. However, when the two phases are mixed, no established results have been obtained. According to the research of many researchers, it is more efficient to mix rutile than 100% anatase (P25-graphene composite as a high performance photocatalyst, Hao Zhang, et al., ACS Nano 4 (2010) 380- 386.) has been reported, and studies showing that the photocatalytic effect appears even when rutile is used alone (influence of rutile structure in TiO2 photocatalytic activity, Seungmin Kim, Tae-Kwan Yoon, Daeil Hong, Journal of the Korean Chemical Society, 49 (6) (2005) 567-574). Titanium dioxide (TiO2), which is currently known to have the best photodegradation efficiency, is a product of Degussa P-25, which is a mixed phase mixture of 70% anatase and 30% rutile.
특히 자외선이 주 에너지가 되는 티타늄디옥사이드(titanium dioxide, TiO2) 광촉매에 있어서 실외 항균, 방오 등의 목적으로 광촉매 사용 시 태양광에 포함된 극히 일부분의 자외선만을 이용하여야 한다는 제한이 있고, 기상변화에 따라 자외선 양이 일정하지 않는 단점을 갖는다. 또한 실내 공기정화 또는 유기화합물 분해 등으로 티타늄디옥사이드(titanium dioxide, TiO2) 광촉매 사용시, 일반적으로 사용되는 형광등은 자외선의 발생을 억제하기 때문에 자외선을 공급해 줄 수 있는 광원이 반드시 필요한 실정이다. 그러므로 태양광 또는 가시광을 효과적으로 이용하여 광촉매의 고유 특성인 방오, 항균, 오염물질 분해 초친수(superhydrophilicity) 등의 성능을 향상시키기 위한 연구와 이를 통한 가시광 응답형 광촉매의 실용화가 절실히 필요한 실정이다.In particular, in the case of titanium dioxide (TiO2) photocatalyst, in which ultraviolet rays are the main energy, when using photocatalysts for the purpose of outdoor antibacterial and antifouling, there is a limitation that only a small portion of ultraviolet rays contained in sunlight should be used. It has the disadvantage that the amount of ultraviolet light is not constant. In addition, when using titanium dioxide (TiO2) photocatalyst for indoor air purification or decomposition of organic compounds, the fluorescent light generally used suppresses the generation of ultraviolet light, so a light source capable of supplying ultraviolet light is essential. Therefore, there is an urgent need for research to improve the performance of anti-fouling, antibacterial, and pollutant decomposition superhydrophilicities, which are the unique properties of photocatalysts, by effectively using sunlight or visible light, and thus to make practical use of visible light-responsive photocatalysts.
가시광 반응형 티타늄디옥사이드(titanium dioxide, TiO2) 광촉매는 금속 원소를 도핑하여 얻을 수 있는데,이를 위한 대표적인 두가지 방법의 장단점은 다음과 같다. (1) 졸-겔 법(Sol-gel method): 상업적인 광촉매 제조방법으로 널리 이용되는 방법 중의 하나로 출발원료에 다양한 금속 또는 귀금속 원소의 도핑이 용이하나 이종원소 도핑에 따른 격자간 뒤틀림, 공공 등과 같은 격자 결함을 새로이 생성하며 이러한 결함은 결과적으로 광촉매 분말의 성능을 저해시키는 원인으로 작용하게 된다. (2) 이온주입법(ion implantation method): 금속원소의 물리적인 주입으로 광촉매의 활성을 가시광 영역으로 크게 이동시킬 수 있지만 분말 또는 박막형성 후 이온을 주입하기 위한 2차공정과 장비가 필요하고 이에 따른 비싼 가격에 의해 실용화가 되기 어렵다. The visible light-reactive titanium dioxide (TiO2) photocatalyst can be obtained by doping a metal element, and the pros and cons of two representative methods for this are as follows. (1) Sol-gel method (Sol-gel method): one of the methods widely used as a commercial photocatalyst manufacturing method. It is easy to do various metal or noble metal elements into the starting material, but warping between grids due to doping of heterogeneous elements, such as vacancy, etc. New lattice defects are generated, and these defects consequently act as a cause of impairing the performance of the photocatalyst powder. (2) Ion implantation method: Physical implantation of a metal element can greatly shift the activity of a photocatalyst into the visible light region, but a secondary process and equipment for implanting ions after powder or thin film formation are required. It is difficult to commercialize due to the high price.
티타늄디옥사이드(titanium dioxide, TiO2)는 자외선을 촉매반응의 에너지원으로 사용하므로 자외선을 투과할 수 없는 거대입자의 경우 촉매 성능 저하의 원인이 될 수 있기 때문에 티타늄디옥사이드(titanium dioxide, TiO2)의 형태 및 크기를 제어하는 기술이 요구된다. 게다가 열공정 조건에 따라 아나타제(anatase)에서 루틸(rutile)로 비가역적 상전이가 일어나게 되어 광촉매 활성에 영향을 미치게 된다. 또한, 금속/비금속 도핑을 하여 티타늄디옥사이드(titanium dioxide, TiO2)의 띠 간격에너지(bandgap energy)를 줄여 가시광 흡수율을 높일 수 있으나, 촉매의 열적 안정성이 떨어져 전자-정공 재결합 속도(electron-hole recombination rate)를 촉진시켜 순수한 티타늄디옥사이드(titanium dioxide, TiO2)에 비해 오히려 활성이 저하된다.Since titanium dioxide (TiO2) uses ultraviolet rays as an energy source for catalytic reactions, the shape of titanium dioxide (TiO2) and A technique for controlling size is required. In addition, irreversible phase transition from anatase to rutile occurs depending on the thermal process conditions, which affects the photocatalytic activity. In addition, it is possible to increase the visible light absorption rate by reducing the bandgap energy of titanium dioxide (Titanium dioxide, TiO2) by doping with metal / nonmetal, but the thermal stability of the catalyst decreases and the electron-hole recombination rate ), And the activity is lowered compared to pure titanium dioxide (TiO2).
티타늄디옥사이드(titanium dioxide, TiO2)는 낮은 흡광도를 가지고 있어 이에 따라 촉매 특성이 저하될 수 있다. 따라서 이를 해결하기 위한 수단으로 높은 흡광도를 가지는 물질과의 결합을 통하여 티타늄디옥사이드(titanium dioxide, TiO2)의 흡광도를 높이는 기술이 요구된다.Titanium dioxide (Titanium dioxide, TiO2) has a low absorbance and thus the catalyst properties may be deteriorated. Therefore, a technique for increasing the absorbance of titanium dioxide (TiO2) through a combination with a material having a high absorbance as a means to solve this is required.
탄소나노섬유(carbon nanofibers, CNFs)는 90% 이상의 탄소원소 질량 함유율을 보유하면서 수백 nm 굵기를 갖는 섬유상의 탄소재료를 지칭하는 것으로 비표면적이 크고, 작은 세공을 이용한 흡착특성이 뛰어나며, 탄소원소의 sp, sp2, sp3의 혼성 결합에 의한 높은 기계적 강도, 우수한 열/전기 전도성, 화학적 안정성 및 생체친화적인 특성을 바탕으로 에너지 저장 및 변환재료(이차전지 전극재료, 슈퍼캐패시터 전극재료, 직접 메탄올 연료전지 촉매 지지체, 염료감응형 태양전지 촉매), 센서, 생체재료, 수 처리 필터, 분리막 등 보다 넒은 응용분야로 그 쓰임이 촉진되어 향후 수요 증가가 예상되고 있다.Carbon nanofibers (CNFs) refers to a fibrous carbon material having a mass content of more than 90% and having a thickness of several hundred nm, and has a large specific surface area, excellent adsorption properties using small pores, and Energy storage and conversion material (secondary battery electrode material, supercapacitor electrode material, direct methanol fuel cell) based on high mechanical strength, excellent thermal / electrical conductivity, chemical stability and bio-friendly properties by sp, sp2, sp3 hybrid bonding Catalyst support, dye-sensitized solar cell catalysts), sensors, biomaterials, water treatment filters, separators, etc. are used in a wider range of applications.
최근 많은 연구그룹에서 티타늄디옥사이드(titanium dioxide, TiO2)를 졸-겔 방법으로 탄소나노섬유 표면에 증착하거나(Preparation of titanium dioxide nanoparticles immobilized on polyacrylonitrile nanofibers for the photodegradation of methyl orange, International Journal of Photoenergy, 2016 (2016) Article ID9 page), 탄소나노섬유의 전구체인 폴리아크릴로니트릴(polyacrylonitrile, PAN)로 티타늄디옥사이드(titanium dioxide, TiO2)의 표면처리(TIO2/cyclized polyacrylonitrile hybridized nanocomposite: An efficient visible-light photocatalyst prepared by a facile "in situ" approach, Qingzhi Luo, et al., Materials Science and Engineering B 199 (2015) 96-104)를 하거나, 전기방사(electrospinning)(Electrospinning of PAN/DMF/H2O containing TiO2 and photocatalytic activity of their webs, Chureerat Prahsarn, et al., Materials Letters 65 (2011) 2498-2501.)하여 복합체를 만들어 가시광 활성 광촉매로 연구하고 있다.Many recent research groups have deposited titanium dioxide (TiO2) on the surface of carbon nanofibers using a sol-gel method (Preparation of titanium dioxide nanoparticles immobilized on polyacrylonitrile nanofibers for the photodegradation of methyl orange, International Journal of Photoenergy, 2016 ( 2016) Article ID9 page), surface treatment of titanium dioxide (TiO2) with polyacrylonitrile (PAN), a precursor to carbon nanofibers (TIO2 / cyclized polyacrylonitrile hybridized nanocomposite: An efficient visible-light photocatalyst prepared by a facile "in situ" approach, Qingzhi Luo, et al., Materials Science and Engineering B 199 (2015) 96-104), or electrospinning (Electrospinning of PAN / DMF / H2O containing TiO2 and photocatalytic activity of Their webs, Chureerat Prahsarn, et al., Materials Letters 65 (2011) 2498-2501.) make complexes and study them as visible light active photocatalysts. The.
종래기술로써 등록특허공보 등록번호 제10-1334294호의 광촉매-그래핀-탄소나노섬유복합체 및 상기 복합체를 포함하는 필터에 의하면, 우수한 전기적 성질과 높은 비표면적을 갖는 그래핀의 장점을 이용하여 가시광에 반응하는 광촉매를 제작하였다. 실험으로 그래핀은 폴리아크릴로니트릴(polyacrylonitrile, PAN)과 함께 전계방사(electrospinning)한 후 탄화시켜 탄소나노섬유로 제작하였고, 탄소나노섬유의 표면에 증착된 티타늄디옥사이드(titanium dioxide, TiO2)는 아나타제(anatase) : 루틸(rutile) = 1 : 1의 비율로 혼재되어 있다. 이 때, 그래핀은 광촉매 입자가 탄소나노섬유 표면에 도포될 때 나노크기로 균일하게 형성시켜 자외선 영역뿐만 아니라 가시광선 영역에서도 높은 광촉매 활성을 보인다고 기술하고 있다.According to the filter comprising the photocatalyst-graphene-carbon nanofiber composite and the composite of the registered patent publication No. 10-1334294 as a prior art, in the visible light using the advantages of graphene having excellent electrical properties and high specific surface area A reactive photocatalyst was prepared. As an experiment, graphene was made of carbon nanofibers by carbonization after electrospinning with polyacrylonitrile (PAN), and titanium dioxide (TiO2) deposited on the surface of the carbon nanofibers was an anatase. (anatase): Rutile = 1: 1 is mixed. At this time, graphene is described that it shows high photocatalytic activity in the visible region as well as in the ultraviolet region by uniformly forming nano-scale when photocatalyst particles are applied to the surface of carbon nanofibers.
그러나 티타늄디옥사이드(titanium dioxide, TiO2)-폴리아크릴로니트릴(polyacrylonitrile, PAN) 혼합액을 동시에 전기방사할 경우 티타늄디옥사이드(titanium dioxide, TiO2)가 폴리아크릴로니트릴(polyacrylonitrile, PAN) 섬유에 묻혀 광 흡수 유효 표면적이 감소하게 되며, 졸-겔 방법으로 제조된 광촉매는 입도가 작고 화학적 균일도가 크다는 장점이 있는 반면 공정에 따른 고비용이 단점으로 지적된다. 또한 광 여기로 형성된 전자 및 정공을 전기전도도가 높은 그래핀을 통해 이동, 분리시켜 전자-정공의 재결합을 막아 효율을 증가시키는 방법이지만 여전히 가시광 영역의 광 흡수율을 증가시킬 수 있는 좁은 밴드갭을 가지는 광촉매의 적용이 요구된다.However, when the titanium dioxide (TiO2) -polyacrylonitrile (PAN) mixture is electrospun simultaneously, titanium dioxide (TiO2) is embedded in polyacrylonitrile (PAN) fibers to effectively absorb light. The surface area is reduced, and the photocatalyst prepared by the sol-gel method has the advantage of small particle size and high chemical uniformity, while high cost according to the process is pointed out as a disadvantage. Also, it is a method to increase the efficiency by preventing electron-hole recombination by moving and separating electrons and holes formed by light excitation through graphene with high electrical conductivity, but it still has a narrow band gap that can increase the light absorption in the visible region. Application of photocatalyst is required.
그래핀양자점(graphene quantum dots, GQDs)은 수 나노미터(nm) 크기의 그래핀 입자로 값싸고 안전한 재료로 이용할 뿐만 아니라 생체적합성과 안정성을 두루 갖추고 있어 최근 다양한 분야에서 연구되고 있다.(Synthesis and properties of photoluminescent carbon quantum dot/polyacrylonitrile composite nanofibers, Smart Science (2017) DOI: 10.1080/23080477.2017.1399318.). 그래핀양자점(graphene quantum dots, GQDs)의 크기 및 표면 상태에 따라 띠 간격에너지(bandgap)를 조절할 수 있어 가시광원을 사용하는 광촉매 분야에서 주목하는 소재이다.Graphene quantum dots (GQDs) are graphene particles of several nanometers (nm) in size, and are used as cheap and safe materials, as well as have biocompatibility and stability, and have been studied in various fields in recent years (Synthesis and properties of photoluminescent carbon quantum dot / polyacrylonitrile composite nanofibers, Smart Science (2017) DOI: 10.1080 / 23080477.2017.1399318.). Graphene quantum dots (GQDs) can be controlled according to the size and surface condition of the bandgap energy (bandgap), so it is a material of interest in the photocatalytic field using a visible light source.
그래핀양자점(graphene quantum dots, GQDs)-티타늄디옥사이드(titanium dioxide, TiO2)가 적용된 가시광 활성 광촉매에 대한 연구가 다양하게 이루어지고 있으나 대부분 아나타제(anatase)에 대한 연구(Quantum-confined bandgap narrowing of TiO2 nanoparticles by graphene quantum dots for visible-light-driven applications, Chem. Commun., 52 (2016) 9208-9211.)이며, 최근에 와서야 루틸(rutile) TiO2가 적용된 광촉매 연구(Surface disordered 루틸(rutile) TiO2-graphene quantum dot hybrids: a new multifunctional material with superior photocatalytic and biofilm eradication properties, A. Biswas, et al., J. Chem. 41 (2017) 2642-2657.)가 이루어지고 있으나 아직 많이 부족한 실정이다.Graphene quantum dots (GQDs) -titanium dioxide (TiO2) -applied visible light-activated photocatalysts have been studied in various ways, but most have been studied with anatases (Quantum-confined bandgap narrowing of TiO2 nanoparticles by graphene quantum dots for visible-light-driven applications, Chem. Commun., 52 (2016) 9208-9211.), and only recently has a photocatalytic study applied with rutile TiO2 (Surface disordered rutile TiO2- graphene quantum dot hybrids: a new multifunctional material with superior photocatalytic and biofilm eradication properties, A. Biswas, et al., J. Chem. 41 (2017) 2642-2657.), but still lacking.
따라서 본 발명은 상기와 같은 문제점을 해결하고자 안출된 것으로, 본 발명의 목적은 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber) 복합체를 이용하여 가시광 촉매 활성이 우수한 광촉매를 제작하는데 있다.Therefore, the present invention was devised to solve the above problems, and the object of the present invention is to use visible light using graphene quantum dots (GQDs) -semiconducting oxide-carbon nanofiber composites. It is intended to produce a photocatalyst with excellent catalytic activity.
또한, 아나타제(anatase)에 비해 광촉매 효율이 낮은 루틸(rutile)을 이용하여 탄소나노섬유, 그래핀양자점 등의 탄소소재를 통해 광촉매 활성의 반응속도를 증가시킨 그래핀양자점-루틸형 티타늄디옥사이드(rutile titanium dioxide)-탄소나노섬유 복합체를 포함하는 광촉매를 제공한다.In addition, graphene quantum dots-rutile-type titanium dioxide (rutile) which increased the reaction rate of photocatalytic activity through carbon materials such as carbon nanofibers and graphene quantum dots using rutile, which has lower photocatalytic efficiency than anatase titanium dioxide) -to provide a photocatalyst comprising a carbon nanofiber composite.
또한, 광촉매 입자의 응집효과를 최소화하고, 광 흡수율을 높이며, 가시광선 영역의 빛을 흡수할 수 있는 광촉매 제조방법을 제공한다.In addition, it provides a method for manufacturing a photocatalyst that minimizes the aggregation effect of photocatalyst particles, increases light absorption, and absorbs light in the visible region.
본 발명의 또 다른 목적은 그래핀양자점-티타늄디옥사이드-탄소나노섬유 복합체에서 광촉매 입자의 유실은 효율 저하를 초래하므로 탄소나노섬유로부터 그래핀양자점-티타늄디옥사이드 입자의 이탈은 비정질 탄소막으로 방지하는 광촉매 제조방법을 제공하고자 하는 것이다.Another object of the present invention is a graphene quantum dot-titanium dioxide-the loss of photocatalyst particles in the carbon nanofiber composite causes an efficiency decrease, so the separation of graphene quantum dot-titanium dioxide particles from the carbon nanofibers is prepared as a photocatalyst to prevent the amorphous carbon film Is to provide a method.
본발명 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매 전극 제조방법은, 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber)를 포함하는 것으로, 팬을 1차가열하여 산화시키는 산화단계; 그래핀양자점(graphene quantum dots, GQDs)과 티타늄디옥사이드(titanium dioxide, TiO2)를 부착하는 GQDs와 TIO2 부착단계; 2차가열하여 열처리 하는 열처리단계; 를 포함하여, 외부전극을 부착하여 광전극으로 사용하는 것을 특징으로 한다.The present invention graphene quantum dots-oxide semiconductor-carbon nanofiber composite photocatalyst electrode manufacturing method, graphene quantum dots (GQDs)-oxide semiconductors (semiconducting oxide)-carbon nanofibers (carbon nanofiber), including the fan Oxidation by primary heating to oxidize; GQDs and TIO2 attachment steps to attach graphene quantum dots (GQDs) and titanium dioxide (TiO2); Heat treatment step of heat treatment by secondary heating; Including, it is characterized in that it is used as a photoelectrode by attaching an external electrode.
따라서 본발명은 높은 전기전도도를 지닌 탄소나노섬유와 그래핀양자점(graphene quantum dots, GQDs)-티타늄디옥사이드(titanium dioxide, TiO2) 광촉매의 결합은 광전극으로 제작 가능하여 물 분해 수소제조용 광전극으로 활용될 수 있는 것으로, 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber) 복합 광촉매에 구리, 인디움, 전도성고분자물질 도포, 등 외부전극을 부착하여 광전극으로 사용, 분해용 전극, 빛을 받아 오염물질 분해용 전극, 수소분해, 가스 분해용으로 사용할 수 있는 현저한 효과가 있다.Therefore, the present invention is a combination of carbon nanofibers with high electrical conductivity and graphene quantum dots (GQDs) -titanium dioxide (TiO2) photocatalyst, which can be manufactured as a photoelectrode and used as a photoelectrode for the production of water-decomposed hydrogen. It can be, graphene quantum dots (GQDs)-oxide semiconductor (semiconducting oxide)-carbon nanofiber (carbon nanofiber) composite photocatalyst, copper, indium, conductive polymer material coating, etc. There is a remarkable effect that can be used as an electrode, an electrode for decomposition, and an electrode for decomposing pollutants by receiving light, for hydrogen decomposition, and for gas decomposition.
도 1은 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber) 복합체 및 외부 전극(external electrode)이 결합된 사진
도 2는 복합체를 이용한 메틸렌블루(methylene blue) 분해 실험 초기 사진
도 3은 복합체를 이용한 메틸렌블루(methylene blue) 분해 실험 조건에서 2시간 반응 후 실험 사진1 is a graphene quantum dots (GQDs)-oxide semiconductor (semiconducting oxide)-carbon nanofiber (carbon nanofiber) composite and an external electrode (external electrode) combined photo
2 is an initial photo of the methylene blue (methylene blue) decomposition experiment using a complex
3 is a photo of the experiment after 2 hours reaction in methylene blue (methylene blue) decomposition experiment conditions using a complex
본 발명은 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매 전극 제조방법이며, 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber)를 포함하는 것으로, 팬을 1차가열하여 산화시키는 산화단계; 그래핀양자점(graphene quantum dots, GQDs)과 티타늄디옥사이드(titanium dioxide, TiO2)를 부착하는 GQDs와 TIO2 부착단계; 2차가열하여 열처리 하는 열처리단계; 를 포함하여, 외부전극을 부착하여 광전극으로 사용하는 것을 특징으로 한다.The present invention is a graphene quantum dot-oxide semiconductor-carbon nanofiber composite photocatalyst electrode manufacturing method, and includes graphene quantum dots (GQDs) -semiconducting oxide-carbon nanofiber, An oxidation step of oxidizing the fan by primary heating; GQDs and TIO2 attachment steps to attach graphene quantum dots (GQDs) and titanium dioxide (TiO2); Heat treatment step of heat treatment by secondary heating; Including, it is characterized in that it is used as a photoelectrode by attaching an external electrode.
또한, 상기 외부전극은 구리, 인디움, 또는 전도성 고분자물질 도포층인 것을 특징으로 한다.In addition, the external electrode is characterized in that the copper, indium, or conductive polymer material coating layer.
또한, 상기 산화물반도체는 아나타제(anatase) 또는 루틸형 티타늄디옥사이드(rutile titanium dioxide)인 것을 특징으로 한다.In addition, the oxide semiconductor is characterized in that it is an anatase or rutile titanium dioxide.
또한, 상기 탄소나노섬유는 폴리아크릴로니트릴(polyacrylonitrile, PAN)섬유인 것을 특징으로 한다.In addition, the carbon nanofibers are characterized by being polyacrylonitrile (PAN) fibers.
본 발명을 첨부도면에 의해 상세히 설명하면 다음과 같다.The present invention will be described in detail with reference to the accompanying drawings.
도 1은 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber) 복합체 및 외부 전극(external electrode)이 결합된 사진, 도 2는 복합체를 이용한 메틸렌블루(methylene blue) 분해 실험 초기 사진, 도 3은 복합체를 이용한 메틸렌블루(methylene blue) 분해 실험 조건에서 2시간 반응 후 실험 사진이다.Figure 1 is a graphene quantum dots (GQDs)-oxide semiconductor (semiconducting oxide)-carbon nanofiber (carbon nanofiber) composite and an external electrode (external electrode) combined photo, Figure 2 is a methylene blue using the complex ( methylene blue) decomposition experiment initial picture, FIG. 3 is a photo after the reaction for 2 hours under methylene blue decomposition experiment conditions using a complex.
본 발명은 그래핀양자점(graphene quantum dots, GQDs)-산화물반도체(semiconducting oxide)-탄소나노섬유(carbon nanofiber) 복합 광촉매에 관한 것으로, 그래핀양자점-산화물반도체-탄소나노섬유를 포함하여 가시광 촉매 활성이 우수한 것이다.The present invention relates to graphene quantum dots (GQDs) -semiconducting oxide-carbon nanofiber composite photocatalyst, including graphene quantum dots-oxide semiconductor-carbon nanofibers for visible light catalytic activity This is excellent.
또한, 상기 산화물반도체는 아나타제(anatase) 또는 루틸형 티타늄디옥사이드(rutile titanium dioxide)인 것이다.Further, the oxide semiconductor is an anatase or rutile titanium dioxide.
또한, 상기 탄소나노섬유는 전계방사된 폴리아크릴로니트릴(polyacrylonitrile, PAN)섬유를 전구체로 사용한 것이다.In addition, the carbon nanofibers are those using electrospun polyacrylonitrile (PAN) fibers as precursors.
또한, 상기 루틸형 티타늄디옥사이드(rutile titanium dioxide)는 순수한 루틸형 티타늄디옥사이드(rutile titanium dioxide)를 사용하거나, 아나타제(anatase) 분말을 열처리하여 상전이(Phase transition)된 루틸(rutile) 분말을 사용하는 것이다.In addition, the rutile titanium dioxide is to use pure rutile titanium dioxide, or heat-translating anatase powder to use phase transitioned rutile powder. .
또한, 상기 그래핀양자점-산화물 반도체-탄소나노섬유의 함량비는 그래핀양자점(graphene quantum dots, GQDs) 8 ~ 12 중량%: 루틸형 티타늄디옥사이드(rutile titanium dioxide) 0.5 ~ 2 중량% : 폴리아크릴로니트릴(polyacrylonitrile, PAN) 91.5 ~ 95중량% 인 것이다.In addition, the content ratio of the graphene quantum dot-oxide semiconductor-carbon nanofiber is 8 to 12% by weight of graphene quantum dots (GQDs): 0.5 to 2% by weight of rutile titanium dioxide: polyacrylic The nitrile (polyacrylonitrile, PAN) is 91.5 to 95% by weight.
또한, 상기 그래핀양자점(graphene quantum dots, GQDs)-루틸형 티타늄디옥사이드(rutile titanium dioxide) 입자는 전계방사된 폴리아크릴로니트릴(polyacrylonitrile, PAN)섬유 표면에 스핀코팅(spin coating) 혹은 딥 코팅(dip coating)법으로 도포되는 것이다.In addition, the graphene quantum dots (GQDs)-rutile titanium dioxide particles are spin-coated or dip coated on the surface of the electrospun polyacrylonitrile (PAN) fiber. dip coating) method.
또한, 상기 산화물반도체는 루틸형 티타늄디옥사이드(rutile titanium dioxide)인 것이다.In addition, the oxide semiconductor is rutile titanium dioxide.
또한, 열처리 공정 중에서 폴리아크릴로니트릴(polyacrylonitrile, PAN)이 탄화되면서 비정질 탄소막이 발생되어 탄소나노섬유로부터 그래핀양자점(graphene quantum dots, GQDs)-티타늄디옥사이드(titanium dioxide, TiO2) 입자의 이탈을 막아 광촉매 양의 손실을 최소화하는 것이다.In addition, during the heat treatment process, polyacrylonitrile (PAN) is carbonized to form an amorphous carbon film to prevent the separation of graphene quantum dots (GQDs) -titanium dioxide (TiO2) particles from carbon nanofibers. It is to minimize the loss of photocatalyst amount.
본 발명의 티타늄디옥사이드(titanium dioxide, TiO2)는 20-50 nm 크기의 아나타제(anatase) 분말(powder), 루틸(rutile) 분말을 이용한다. 이는 광촉매의 함량을 조절하기 용이하고 광촉매 입자의 응집효과를 최소화하는 효과가 있다.The titanium dioxide (Titanium dioxide, TiO2) of the present invention uses an anatase (powder), rutile (rutile) powder having a size of 20-50 nm. This has an effect of easily controlling the content of the photocatalyst and minimizing the aggregation effect of the photocatalyst particles.
탄소나노섬유는 그래핀양자점(graphene quantum dots, GQDs)-티타늄디옥사이드(titanium dioxide, TiO2)의 지지체이면서 동시에 질소와 탄소의 도펀트(dopant)로서 역할을 한다. 그래핀양자점(graphene quantum dots, GQDs)는 화학적 박리법을 통해 합성되었으며, 티타늄디옥사이드(titanium dioxide, TiO2)는 그래핀양자점(graphene quantum dots, GQDs)이 도포된 루틸(rutile) 입자를 사용한다. 즉, 순수 루틸(rutile) 입자, 또는 열처리를 통해 아나타제(anatase)에서 루틸로 상전이를 한 입자, 그리고 그래핀양자점(graphene quantum dots, GQDs)이 탄소나노섬유에 결합된 광촉매 복합체를 이용하여 실내용 인공광원에서 광분해 반응에 의한 수질 오염물을 효과적으로 제거할 수 있다.Carbon nanofibers are graphene quantum dots (GQDs)-a support for titanium dioxide (TiO2) and at the same time serve as a dopant for nitrogen and carbon. Graphene quantum dots (GQDs) were synthesized through chemical exfoliation, and titanium dioxide (TiO2) uses rutile particles coated with graphene quantum dots (GQDs). That is, pure rutile particles, or particles that have undergone phase transition from anatase to rutile through heat treatment, and graphene quantum dots (GQDs) are used for indoor use using photocatalytic composites bonded to carbon nanofibers. It is possible to effectively remove water pollutants caused by photolysis reactions from artificial light sources.
그래핀양자점(graphene quantum dots, GQDs)은 화학적 박리법을 통해 얻는다. 공정 온도는 오일 배스(oil bath) 기준 80~200℃이다.Graphene quantum dots (GQDs) are obtained by chemical exfoliation. Process temperature is 80 ~ 200 ℃ based on oil bath.
그래핀양자점(graphene quantum dots, GQDs)-티타늄디옥사이드(titanium dioxide, TiO2) 입자는 수용액 상태에서 두 재료를 스터링(stirring)과 초음파 처리를 하여 얻는다.Graphene quantum dots (GQDs) -titanium dioxide (TiO2) particles are obtained by stirring and sonication the two materials in aqueous solution.
그래핀양자점-티타늄디옥사이드-탄소나노섬유 복합체의 티타늄디옥사이드는 루틸(rutile)의 형태를 이용하는데, 루틸(rutile)을 얻는 방법으로는 순수한 루틸(rutile) 분말을 그대로 사용하는 것과 아나타제(anatase) 분말을 열처리하여 상전이(Phase transition)된 루틸(rutile) 분말을 사용한다.The graphene quantum dot-titanium dioxide-titanium dioxide of the carbon nanofiber composite uses the form of rutile. As a method of obtaining rutile, pure rutile powder is used as it is and anatase powder By heat treatment, a rutile powder with phase transition is used.
전계방사된 폴리아크릴로니트릴(polyacrylonitrile, PAN)섬유 표면에 스핀코팅(spin coating) 혹은 딥 코팅(dip coating)법으로 그래핀양자점-티타늄디옥사이드 입자를 도포한다. 특히 폴리아크릴로니트릴(polyacrylonitrile, PAN)은 그대로 사용할 수 있으나, 전계방사하면 3d 형태 탬플릿 만들 수 있게 표면적이 넓어지고 붙이는 입자가 많아진다. 표면적 넓어지므로 반응성 좋으므로 전극으로 활용이 좋다.Graphene quantum dot-titanium dioxide particles are coated on the surface of the electrospun polyacrylonitrile (PAN) fiber by spin coating or dip coating. In particular, polyacrylonitrile (PAN) can be used as it is, but when the electric field is radiated, the surface area is widened and the number of particles to be attached increases to make a 3d template. As the surface area is wide, it has good reactivity, so it can be used as an electrode.
준비된 그래핀양자점-티타늄디옥사이드-폴리아크릴로니트릴은 진공 도가니(vacuum furnace)로 열처리 하여 그래핀양자점-티타늄디옥사이드-탄소나노섬유 복합체를 제작한다. 본발명은 내부에 팬을 230 ~ 250℃로 산화시킨후 팬에 그래핀양자점과 티타늄디옥사이드를 부착하는 것으로, 통상 300℃ 이후에서 붙이며, 300℃이후부터 붙이는 이유는 그 전 산화온도에서는 그래핀양자점이 산화되면서 떨어져나가므로 목적달성이 안 된다. 이후 열처리 온도는 300 ~ 600℃으로 한다.The prepared graphene quantum dot-titanium dioxide-polyacrylonitrile is heat-treated with a vacuum crucible to prepare a graphene quantum dot-titanium dioxide-carbon nanofiber composite. The present invention is to attach the graphene quantum dots and titanium dioxide to the pan after oxidizing the pan to 230 ~ 250 ° C in the inside. Usually, it is pasted after 300 ° C. As it oxidizes and falls off, it does not achieve its purpose. Thereafter, the heat treatment temperature is set to 300 to 600 ° C.
높은 전기전도도를 지닌 탄소나노섬유와 그래핀양자점-티타늄디옥사이드 광촉매의 결합은 광전극으로 제작 가능하여 물 분해 수소제조용 광전극으로 활용될 수 있다. 곧 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매를 이용하여 광전극으로 사용하는 것은 결과물 자체가 전극이다. 그리고 구리, 인디움, 전도성고분자물질 도포, 등 외부전극을 부착하여 광전극으로 사용, 목적 분해용 전극, 빛을 받아 오염물질 분해용 전극, 수소분해, 가스 분해용으로 효과적으로 사용할 수 있다.The combination of carbon nanofiber with high electrical conductivity and graphene quantum dot-titanium dioxide photocatalyst can be manufactured as a photoelectrode, and thus can be used as a photoelectrode for water-decomposition hydrogen production. Soon, the use of graphene quantum dot-oxide semiconductor-carbon nanofiber composite photocatalyst as the photoelectrode is the result itself. In addition, copper, indium, conductive polymer material coating, etc. can be used as an optical electrode by attaching an external electrode, an electrode for purpose decomposition, an electrode for decomposing pollutants under light, hydrogen decomposition, and gas decomposition.
또한, 제조된 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매를 분말제품으로 사용하는 것으로, 2나노미터(nm) 크기의 그래핀양자점-30나노미터(nm) 크기의 산화물반도체-탄소나노섬유 복합 광촉매를 소닉이나 볼밀 분말로 사용하는 것으로 분말화된 결과물의 크기는 10 ~ 300나노미터(nm)이다.In addition, the prepared graphene quantum dot-oxide semiconductor-carbon nanofiber composite photocatalyst is used as a powder product, and a 2 nanometer (nm) -sized graphene quantum dot-30 nanometer (nm) -sized oxide semiconductor-carbon nanofiber By using a composite photocatalyst as a sonic or ball mill powder, the size of the powdered product is 10 to 300 nanometers (nm).
팬은 전기방사된 섬유나 플레이트 상태로 사용될 수 있다.The fan can be used in the form of electrospun fibers or plates.
한편, 본발명은 패드로 사용하는 것으로, 그래핀양자점-산화물반도체-탄소나노섬유 복합 광촉매를 300 ~ 600℃로 가열하여 가요성이 있는 패드로 사용하는 것이다.On the other hand, the present invention is to be used as a pad, the graphene quantum dot-oxide semiconductor-carbon nanofiber composite photocatalyst is heated to 300 ~ 600 ℃ to use as a flexible pad.
좁은 밴드갭을 가지는 그래핀양자점(graphenequantum dots, GQD)은 가시광 영역을 흡수하는 광흡수체 역할을 하며, 동시에 티타늄디옥사이드(titanium dioxide, TiO2)와의 계면에서 쇼트키 장벽을 만들어 전자-정공의 재결합을 막아 광촉매 효율을 높인다. 또한, 단일 열처리 공정을 통해 탄소나노섬유(carbon nanofiber)를 도펀트로 활용하여 광촉매의 탄소 및 질소의 도핑을 통해 루틸형 티타늄디옥사이드(rutile titanium dioxide)의 광흡수율을 높이고 가시광 영역에서 반응하는 광촉매를 얻을 수 있다.Graphene quantum dots (GQD) with a narrow band gap act as a light absorber absorbing the visible light region, and at the same time create a Schottky barrier at the interface with titanium dioxide (TiO2) to prevent electron-hole recombination. Increase photocatalytic efficiency. In addition, the carbon nanofiber is used as a dopant through a single heat treatment process to increase the light absorption of rutile titanium dioxide through doping of carbon and nitrogen of the photocatalyst and obtain a photocatalyst that reacts in the visible light region. You can.
폴리아크릴로니트릴(polyacrylonitrile, PAN)이 탄화되는 과정에서 아나타제(anatase)가 루틸(rutile)로 상전이 하면서 폴리아크릴로니트릴(polyacrylonitrile, PAN)로부터 탄소,질소 도핑이 동시에 이루어져 별도의 도핑을 위한 조건이 요구되지 않는다.In the process of polyacrylonitrile (PAN) carbonization, anatase phase changes to rutile, while carbon and nitrogen doping are simultaneously performed from polyacrylonitrile (PAN) to provide separate doping conditions. Is not required.
열처리 공정 중에서 폴리아크릴로니트릴이 탄화되면서 발생되는 비정질 탄소막은 탄소나노섬유로부터 그래핀양자점(graphene quantum dots, GQDs)-티타늄디옥사이드(titanium dioxide, TiO2) 입자의 이탈을 막아 광촉매 양의 손실을 최소화한다.The amorphous carbon film generated by carbonization of polyacrylonitrile during the heat treatment process minimizes the loss of photocatalyst amount by preventing the separation of graphene quantum dots (GQDs) -titanium dioxide (TiO2) particles from carbon nanofibers. .
곧, 비정질에 대해 설명하면, 폴리아크릴로니트릴이 탄화되며, 일부 탄소는 티타늄디옥사이드(titanium dioxide, TiO2)에 탄소 도펀트로 도핑에 참여하고, 나머지 내부 탄소들이 기화되며 방출되며 표면에 달라붙는데 , 곧 재흡착되는 것으로 이는 완벽한 박막은 아니다. 어느 정도 얼기설기 엮여 전체적으로 표면을 덮는다. 표면의 입자들이 떨어지지 않게 바인딩 역할을 한다.Soon, when it comes to amorphous, polyacrylonitrile is carbonized, some carbon participates in doping with titanium dioxide (TiO2) as a carbon dopant, and the remaining internal carbons are vaporized and released and stick to the surface. Resorption, which is not a perfect thin film. It is interwoven to some extent and covers the surface as a whole. It serves as a binding so that the particles on the surface do not fall off.
구체적으로 본 발명의 그래핀양자점(graphene quantum dots, GQDs), TIO2, 폴리아크릴로니트릴 기반 탄소나노섬유에 대해 설명하면 본 발명의 그래핀양자점(graphene quantum dots, GQDs)은 광흡수체(가시광선으로 확산)이며, 티타늄디옥사이드(titanium dioxide, TiO2)는 광촉매, 광흡수체이며, 폴리아크릴로니트릴 기반 탄소나노섬유는 탄소/질소도핑(광흡수체의 가시광선 흡수 활성을 높인다)에 의해 티타늄디옥사이드(titanium dioxide, TiO2)의 새로운 도핑 준위를 형성하여 가시광선에도 반응하는 에너지밴드 구조로 바꾼다. 또한 폴리아크릴로니트릴 기반 탄소나노섬유는 높은 전도도를 가지고 있으므로 그래핀양자점(graphene quantum dots, GQDs)이나 티타늄디옥사이드(titanium dioxide, TiO2)에서 생성된 전자정공쌍을 빨리 다른 곳으로 이동시켜 재결합을 방지하여 광효율을 향상한다. 광흡수에 의해 생성된 전자와 정공의 본래 알려진 목적은 광촉매 및 탄소나노섬유 표면에서 분해 활성도를 높이는데 참여한다.Specifically, the graphene quantum dots (GQDs), TIO2, and polyacrylonitrile-based carbon nanofibers of the present invention are described. The graphene quantum dots (GQDs) of the present invention are light absorbers (visible light). Diffusion), titanium dioxide (Titanium dioxide, TiO2) is a photocatalyst, light absorber, and polyacrylonitrile-based carbon nanofibers are titanium dioxide (titanium dioxide) by carbon / nitrogen doping (enhancing the light absorber's visible light absorption activity) , TiO2) to form a new doping level and change to an energy band structure that responds to visible light. In addition, since polyacrylonitrile-based carbon nanofibers have high conductivity, electron hole pairs generated from graphene quantum dots (GQDs) or titanium dioxide (TiO2) are quickly moved to other places to prevent recombination. To improve light efficiency. The originally known purpose of electrons and holes produced by light absorption is to participate in increasing the decomposition activity on the surface of photocatalysts and carbon nanofibers.
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| KR20230132125A (en) * | 2022-03-08 | 2023-09-15 | 영남대학교 산학협력단 | TiO2 nanocomposite electrode using nitrogen-doped graphene quantum dot and quantum dot-sensitized solar cell |
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