• Proceedings of the Korean Institute of Surface Engineering Conference
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• 2018.06a
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• pp.51-51
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• 2018

산업의 발달 및 인구 증가에 따라 발생되는 폐수의 종류는 다양해지고 있으며, 폐수의 처리를 위해서는 주로 생물학적 처리를 먼저 검토하게 된다. 하지만 최근 폐수의 성분은 생물학적으로 처리하기 어려운 난분해성 요인(고농도의 염분, 독성 유기용매, 중금속 등)이 존재 할 뿐 아니라, 생물학적 처리 후 존재하는 잔류 유기물은 환경부에서 제시하는 방류수 기준을 만족시키기에 어려움이 있다. 이러한 난분해성 요인을 제거하기 위해서 전기 화학적 처리의 필요성이 대두되고 있으며, 다양한 고도산화기술들이 제시되고 있다. 그 중 처리시간의 단축으로 인한 처리비용 절감과 산화제 발생에 따른 높은 처리 효율로 인해 전기화학적 폐수산화처리에 대한 연구가 활발히 진행되고 있는 실정이다. 본 연구에서는 기존에 사용되어 지고 있는 전기화학적 폐수산화처리를 위한 불용성 전극을 BDD 전극으로 대체하여 다양한 폐수에 전기분해 처리 적용 가능성을 검토하고자 기존 BDD 전극의 기판 모재로 이용되던 Si, Nb 대신에 Ti 기판 위에 BDD 형성시켜 전극을 제작하였고, 폐수의 전기분해 적용 가능성을 확인하기 위하여 축산폐수, 해양폐수, 질산염폐수 등 실제 폐수를 채수하여 폐수 내 유기물의 전기분해 처리 효율을 분석하였다. 이에 Ti 모재 기판에 증착된 BDD 전극을 이용하여 폐수 내 유기물의 전기분해 처리효율을 분석 한 결과, 축산폐수의 경우 처리시간 150분에 95% 이상 처리효율을 나타냈으며, 해양폐수의 경우 처리시간 60분에 98% 이상의 유기물 제거 효결과가 나타남에 따라 축산폐수와 선박 평형수, 양식장폐수 등 다양한 폐수에 적용이 가능할 것으로 판단되며, 기존에 적용되어 지고 있는 고도산화처리 기술을 BDD 전극을 이용한 전기화학적 처리로 대체 할 수 있을 것으로 기대할 수 있다.

• Proceedings of the Korean Vacuum Society Conference
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• 2016.02a
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• pp.168-168
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• 2016

BDD(Boron Doped Diamond) 전극은 전위창이 넓고, 다른 불용성 전극에 비해 산소발생과전압이 높아 물을 전기화학적인 방법으로 처리하는 영역에 있어 매우 효과적일 뿐만 아니라, 전통적인 불용성 전극에 비해 전극 표면에서 수산화 라디칼(-OH)과 오존(O3)의 발생량이 월등히 높아 수처리용 전극으로서의 유용성이 매우 높다. 따라서 BDD 전극을 수처리용 전극에 사용하는 경우 수산화 라디칼(-OH)과 오존(O3), 과산화수소(H2O2) 등과 같은 산화제의 생성은 물론이고, 염소(Cl2)가 포함되어 있는 전해액에서는 차아염소산(HOCl)이나 차아염소산이온(OCl-)과 같은 강력한 산화제가 발생되어 전기화학적 폐수처리, 전기화학적 정수처리, 선박평형수 처리 등의 분야에 널리 활용될 수 있다. 본 연구에서는 상온 및 상압에서 운전이 가능하고 난분해성 오염물질 제거 효과가 뛰어난 전기화학적 고도산화공정(Electrochemical Advanced Oxidation Process, EAOP)에 적합한 대면적의 BDD 전극을 개발하고 자 하였다. 이러한 BDD 전극의 성막 방법으로는 필라멘트 가열 CVD, 마이크로파 플라즈마 CVD, DC 플라즈마 CVD 등이 널리 알려져 있는데 최근에는 설비의 투자비가 비교적 저렴하고, 대면적의 기판처리가 용의한 필라멘트 가열 화학기상증착법(Hot Filament Chemical Vapor Deposition, HFCVD)이 상업적으로 각광을 받고 있다. 따라서 본 연구에서는 HFCVD 방법을 이용하여 반응 가스의 투입비율, BDD 박막의 두께, 기판의 재질 등에 따른 여러 가지 성막 조건들을 검토하여 $100{\times}100mm$ 이상의 대면적 BDD 전극을 개발하였다. Fig. 1은 본 연구를 통하여 얻어진 BDD 전극의 표면 및 단면 SEM이다.

• Applied Chemistry for Engineering
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• v.29 no.1
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• pp.117-121
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• 2018

A stainless steel mesh was applied to the cathode of an electro-Fenton system. Methylene blue (MB) solution was chosen as the model waste water with non-biodegradable pollutants. For the model waste water, the degradation efficiency was compared among various SUS mesh cathodes with different surface treatments and magnetite coatings on them. With increasing amount of the magnetite coating on SUS mesh, the degradation efficiency also increased. The improved electro-catalytic characteristic was explained by the increased amount of in situ generated hydrogen peroxide near the cathode surface. Cyclic voltammetry data also showed improved electro-catalytic performance for SUS mesh with more magnetite coatings on them.

• Proceedings of the Korean Institute of Surface Engineering Conference
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• 2016.11a
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• pp.191.2-191.2
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• 2016

$TiO_2$는 우수한 화학적 및 물리적 안정성 때문에 수전해 장기간 사용에 적합한 전기화학 전극으로 여겨진다. 큰 표면적을 갖는 $TiO_2$를 제조하기 위한 수많은 방법 중 양극산화(anodization)는 비교적 간단하고 저렴한 공정으로 인하여 매우 실용적인 방법으로서 알려져 있다. 특히, 고도로 정렬 된 $TiO_2$ 나노튜브($TiO_2$ NTs) 의 경우에는 분말상과 달리 전극제조를 위해 추가적인 접착제를 필요하지 않다. 그러나, $TiO_2$는 일반적으로 절연 특성을 나타내기 때문에 전극의 활용을 위해서는 본질적으로 촉매의 사용이 불가피하다. 다수의 전기 촉매 중, $IrO_2$와 $RuO_2$는 수전해 분야에 잘 알려진 산화 촉매이다. 그럼에도 불구하고, 특유의 높은 종횡비 때문에 $TiO_2$ 나노튜브에 전기 촉매를 균일하게 도핑하는 것은 많은 어려움이 따른다. 이를 해결하기 위한 방법으로 $RuO_2$를 도핑하기 위한 단일공정 $TiO_2$ 양극산화 기술이 보고된 바 있다. 본 연구에서는 2원 촉매($IrO_2$ 및 $RuO_2$)를 $TiO_2$ 나노튜브에 도핑하기 위한 단일공정 양극산화 기술에 대하여 연구하였다. 전구물질로써 $KRuO_4$($RuO_2$ 전구체)와 IrOx 나노입자(IrOx NPs, $IrO_2$ 전구체)를 사용하였다. 특히, IrOx를 나노 입자는 $IrCl_3$로부터 중간 매체로 합성된다. IrOx는 단일공정 양극산화 중에 $TiO_2$ 나노튜브 상에 도핑 가능한 이온 형태인 $IrO_4$-로 전환될 수 있다. 제조된 시료는 열처리 후 바로 전극으로 사용되었으며 SEM, XPS, TEM, ICP-OES 등으로 정성, 정량 분석을 수행하였다. LSV와 EIS를 통해 전기화학적 성능 평가가 이루어졌으며, LSV를 통해 포집한 기체는 가스 크로마토그래피를 사용하여 정량분석한 후 그 효율을 측정하였다.

• Journal of Korean Society of Environmental Engineers
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• v.38 no.12
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• pp.647-655
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• 2016

Lead dioxide ($PbO_2$) is an electrode material that is effective for organic pollutant degradation based on hydroxyl radical ($^{\bullet}OH$) attack. Representative parameters for $PbO_2$ electrodeposition are summarized to current, temperature, reaction time, concentration of Pb(II) and electrolyte agent. In this study, $Ti/PbO_2$ electrodes were fabricated by electrodeposition method under controlled reaction time, current density, temperature, concentration of $HNO_3$ electrolyte. Effects of deposition parameters on $^{\bullet}OH$ evolution were investigated in terms of electrochemical bleaching of p-Nitrosodimethylaniline (RNO). As major results, the $^{\bullet}OH$ evolution was promoted at the $PbO_2$ that was deposited in longer reaction time (1-90 min), lower current density ($0.5-50mA/cm^2$), higher temperature ($5-65^{\circ}C$) and lower $HNO_3$ concentration (0.01-1.0 M). Especially, the $PbO_2$ which was deposited in 0.01 M of lowest $HNO_3$ concentration by applying $20mA/cm^2$ for above 10 min was most effective on $^{\bullet}OH$ evolution. The performance gap between $PbO_2$s that was best and worst in $^{\bullet}OH$ evolution was about 41%. Among the properties of $PbO_2$ related on $^{\bullet}OH$ evolution performance, conductivity of $Ti/PbO_2$ significantly influenced on $^{\bullet}OH$ evolution. The increase in conductivity promoted $^{\bullet}OH$ evolution. In addition, the increase in crystal size of $PbO_2$ interfered $^{\bullet}OH$ evolution at surface of some $PbO_2$ deposits.

• Journal of Korean Society of Water and Wastewater
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• v.33 no.1
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• pp.31-41
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• 2019

Volatile organic compounds(VOCs) are toxic carcinogenic compounds found in wastewater. VOCs require rapid removal because they are easily volatilized during wastewater treatment. Electrochemical advanced oxidation processes(EAOPs) are considered efficient for VOC removal, based on their fast and versatile anodic electrochemical oxidation of pollutants. Many studies have reported the efficiency of removal of various types of pollutants using different anodes, but few studies have examined volatilization of VOCs during EAOPs. This study examined the removal efficiency for VOCs (chloroform, benzene, trichloroethylene and toluene) by oxidization and volatilization under a static stirred, aerated condition and an EAOP to compare the volatility of each compound. The removal efficiency of the optimum anode was determined by comparing the smallest volatilization ratio and the largest oxidization ratio for four different dimensionally stable anodes(DSA): Pt/Ti, $IrO_2/Ti$, $IrO_2/Ti$, and $IrO_2-Ru-Pd/Ti$. EAOP was operated under same current density ($25mA/cm^2$) and electrolyte concentration (0.05 M, as NaCl). The high volatility of the VOCs resulted in removal of more than 90% within 30 min under aerated conditions. For EAOP, the $IrO_2-Ru/Ti$ anode exhibited the highest VOC removal efficiency, at over 98% in 1 h, and the lowest VOC volatilization (less than 5%). Chloroform was the most recalcitrant VOC due to its high volatility and chemical stability, but it was oxidized 99.2% by $IrO_2-Ru/Ti$, 90.2% by $IrO_2-Ru-Pd/Ti$, 78% by $IrO_2/Ti$, and 75.4% by Pt/Ti anodes The oxidation and volatilization ratios of the VOCs indicate that the $IrO_2-Ru/Ti$ anode has superior electrochemical properties for VOC treatment due to its rapid oxidation process and its prevention of bubbling and volatilization of VOCs.

• Journal of the Korea institute for structural maintenance and inspection
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• v.23 no.4
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• pp.61-68
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• 2019

As the pollution of water resources deteriorates due to industrialization and urbanization, it is difficult to supply clean water through a water treatment method using chlorine. Therefore, the introduction of advanced water treatment facilities using ozone is on the increase. However, epoxy which is used as waterproofing and anticorrosives and stainless steel used in conventional waterproofing and anti-corrosive methods have deteriorated because of the strong oxidizing power of ozone, causing problems such as leaking. Moreover, it even causes the durability degradation of a concrete. Therefore, in this study, metal spraying system was used as the means of constructing a metal panel with excellent ozone resistance and chemical resistance which is an easier method than an existing construction method. Ozone resistance was evaluated in accordance with the type of metal sprayed coatings to develop a finishing method which can prevent the concrete structure of water treatment facilities from deterioration. Furthermore, electrochemical stability in actual sewage treatment plant environment was evaluated. Experimental results showed that Ti has superior ozone resistance after spraying and the electrochemical stability in the sewage treatment plant environment showed that Ti has the highest polarization resistance of $403.83k{\cdot}{\Omega}{\cdot}cm^2$, which ensures high levels of durability.

• Journal of Advanced Marine Engineering and Technology
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• v.37 no.5
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• pp.484-492
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• 2013

With the industrial acceleration in a lot of countries of the world, the demand for anti-corrosion and anti-abrasion material increases continuously. Particularly, stainless steel with the fine surface and excellent corrosion resistance is widely used in various industrial fields including ship, offshore structures tidal power plant, and etc. In marine environment, however, it is easy to generate by the corrosion damage by $Cl^-$ ion and cavitation damage due to high rotation speed on stainless steel. Therefore, in this research, the cavitation erosion-corrosion test (Hybrid test) was performed for 304 stainless steel specimen used in the high flow rate seawater environment. And the cavitation damage behavior in the corrosive environment was analyzed overall. The high hardness was shown due to the formation of compressive residual stress by the water cavitation peening effect in cavitation condition. However, high current density in the potentiodynamic polarization experiment presented with the breakdown of the passive film caused by physical impact. Therefore, both electrochemical characteristics and mechanical properties must be taken into account to improve the cavitation resistance in seawater.

• Journal of Korean Society of Water and Wastewater
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• v.32 no.4
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• pp.349-355
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• 2018

This study interrogated multi-layer heterojunction anodes were interrogated for potential applications to water treatment. The multi-layer anodes with outer layers of $SnO_2/Bi_2O_3$ and/or $TiO_2/Bi_2O_3$ onto $IrO_2/Ta_2O_5$ electrodes were prepared by thermal decomposition and characterized in terms of reactive chlorine species (RCS) generation in 50 mM NaCl solutions. The $IrO_2/Ta_2O_5$ layer on Ti substrate (Anode 1) primarily served as an electron shuttle. The current efficiency (CE) and energy efficiency (EE) for RCS generation were significantly enhanced by the further coating of $SnO_2/Bi_2O_3$ (Anode 2) and $TiO_2/Bi_2O_3$ (Anode 3) layers onto the Anode 1, despite moderate losses in electrical conductivity and active surface area. The CE of the Anode 3 was found to show the highest RCS generation rate, whereas the multi-junction architecture (Anode 4, sequential coating of $IrO_2/Ta_2O_5$, $SnO_2/Bi_2O_3$, and $TiO_2/Bi_2O_3$) showed marginal improvement. The microscopic observations indicated that the outer $TiO_2/Bi_2O_3$ could form a crack-free layer by an incorporation of anatase $TiO_2$ particles, potentially increasing the service life of the anode. The results of this study are expected to broaden the usage of dimensionally stable anodes in water treatment with an enhanced RCS generation and lifetime.

• Journal of the Korean Applied Science and Technology
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• v.35 no.3
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• pp.612-621
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• 2018

In this study, $TiO_2$ nanotube plate and metal electrodes(Copper, Nickel, Stainless Steel, Aluminum, Tin, Titanium) were compared on cathodic reduction of nitrate ($NO_3{^-}-N$) during electrolysis. The electrochemical characteristics were compared based on electrochemical impedance spectroscopy (EIS). The surface morphology was obtained using scanning electron microscopy (SEM) method. Brunauer-Emmett-Teller (BET) method was implemented for the specific surface area analysis of the cathodes. To study kinetics, 90 minute batch electrolysis of nitrate solution was performed for each cathodes. In conclusion, under the condition of relatively low ($0.04 A\;cm^{-2}$) current density, $TiO_2$ nanotube plate showed no surface corrosion during the electrolysis, and the reaction rate was measured the highest in the kinetic analysis.