• 물과 미래
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• 제23권3호
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• pp.363-371
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• 1990

본연구는 정수처리에 있어서의 적정염소주입제어를 위한 산화환원전위법의 활용가능성에 대한 기초적 검토를 실시한 것이다. 연구실험을 통하여, 원수의 염소화반응에 미치는 pH와 온도 및 산화환원전위의 재현성에 대하여 평가하였다. 수도원수의 불연속점부근에 있어서의 산화환원전위의 검출은 불연속점적정곡선의 작성에 의하여 이루어졌으며, 이로 인하여 본방법의 염소처리제어에의 기본적인 활용가능성이 확인되었다.

• Bulletin of the Korean Chemical Society
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• 제31권11호
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• pp.3118-3122
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• 2010

The water soluble redox polymer, poly(N-vinylimidazole) complexed with Os(4,4'-dichloro-2,2'-bipyridine)$_2Cl]^+$ (PVI-[Os(dCl-bpy)$_2Cl]^+$), was electrodeposited on the surface of a glassy carbon electrode by applying cycles of alternating square wave potentials between 0.2 V (2 s) and 0.7 V (2 s) to the electrode in a solution containing the redox polymer. The coordinating anionic ligand, $Cl^-$ of the osmium complex, became labile in the reduced state of the complex and was substituted by the imidazole of the PVI chain. The ligand substitution reactions resulted in crosslinking between the PVI chains, which made the redox polymer water insoluble and caused it to be deposited on the electrode surface. The deposited film was still electrically conducting and the continuous electrodeposition of the redox polymer was possible. When cycles of square wave potentials were applied to the electrode in a solution of bilirubin oxidase and the redox polymer, the enzyme was co-electrodeposited with the redox polymer, because the enzymes could be bound to the metal complexes through the ligand exchange reactions. The electrode with the film of the PVI-[Os(dCl-bpy)$_2Cl]^+$ redox polymer and the co-electrodeposited bilirubin oxidase was employed for the reduction of $O_2$ and a large increase of the currents was observed due to the electrocatalytic $O_2$ reduction with a half wave potential at 0.42 V vs. Ag/AgCl.

• 한국지하수토양환경학회지:지하수토양환경
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• 제25권1호
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• pp.25-36
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• 2020

In a redox transition zone, geochemical reactions are facilitated by active bacteria that mediate reactions involving electrons, and arsenic (As) and iron (Fe) cycles are the major electron transfer reactions occurring at such a site. In this study, the effect of repetitive redox changes on soil bacterial community in As-contaminated soil was investigated. The results revealed that bacterial community changed actively in response to redox changes, and bacterial diversity gradually decreased as the cycle repeated. Proportion of strict aerobes and anaerobes decreased, while microaerophilic species such as Azospirillum oryzae group became the predominant species, accounting for 72.7% of the total counts after four weeks of incubation. Bacterial species capable of reducing Fe or As (e.g., Clostridium, Desulfitobacterium) belonging to diverse phylogenetic groups were detected. Indices representing richness (i.e., Chao 1) and phylogenetic diversity decreased from 1,868 and 1,926 to 848 and 1,121, respectively. Principle component analysis suggests that repetitive redox fluctuation, rather than oxic or anoxic status itself, is an important factor in determining the change of soil bacterial community, which in turn affects the cycling of As and Fe in redox transition zones.

• 한국미생물·생명공학회지
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• 제35권1호
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• pp.36-40
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• 2007

Redox signaling은 단백질을 산화환원 시키는 세포의 중요 신호가 전달되어, 그 단백질의 기능이 변화함으로써 세포의 성장 및 사멸을 조절하게 되는 과정이다. 단백질 합성 구성원의 산화, 환원 과정에 의한 단백질 합성 조절을 알아보기 위해 환원제인 DTT 존재 하에 단백질 합성 활성을 관찰한 결과 DTT가 존재하지 않는 것에 비해 단백질합성이 1.4배 정도 증가됨이 관찰되어 redox potential을 보이는 것으로 보아 환원제가 단백질 합성을 좀 더 증진시키는 것으로 사료된다. DTT에 의한 이러한 현상은 산화환원 조절 단백질인 thioredoxin를 첨가한다면 thiol기에 환원력이 전달되어 단백질합성이 더욱 촉진되기 때문에 효모에서 thioredoxin유전자를 cloning하고 이로부터 효모에서 GST-thioredoxin을 분리하였다. DTT 존재 하에 산화환원 조절 단백질인 thioredoxin을 농도별로 첨가하였을 때의 단백질 합성이 어떻게 조절되는지 알아보았다. 반응 액에 DTT를 넣은 것과 넣지 않은 것을 사용하여 thioredoxin을 0ng, 18ng, 90ng, 460ng, 2,300 ng의 농도로 각각 넣어서 반응시켜 보았다. 이렇게 반응시킨 반응물에서 만들어진 단백질 활성을 측정하였는데 thioredoxin의 농도가 높아질수록 그 활성이 높게 나타났으며, thioredoxin을 넣은 것이 넣지 않은 것에 비해 활성이 약 4배 이상 높게 나왔다 이 결과는 산화환원 조절 단백질인 thioredoxin이 환원력을 단백질합성구성원에 효율적으로 전달하는데 관여함을 보여주는 것이며, 산화환원이 단백질 합성 시 중요한 신호전달 과정임을 암시한다.

• 한국전기화학회:학술대회논문집
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• 한국전기화학회 2002년도 춘계총회 및 학술발표회
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• pp.7-7
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• 2002

• Korean Chemical Engineering Research
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• 제53권5호
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• pp.638-645
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• 2015

Vanadium redox flow batteries (VRFBs) have been investigated for their potential utility as large energy storage systems due to their advantageous performances in terms of long cycle life, high energy efficiency, low cost, and flexible design. Carbon materials are typically used as electrodes in redox reactions and as a liquid electrolyte support. The activities, surface areas, and surface morphologies of porous carbon materials must be optimized to increase the redox flow battery performance. Here, to reduce the resistance in VRFBs, surface-modified carbon felt electrodes were fabricated, and their structural, morphological, and chemical properties were characterized. The surface-modified carbon felt electrode improved the cycling energy efficiencies in the VRFBs, from 65% to 73%, due to the improved wettability with electrolyte. From the results of impedances analysis with proposed fitting model, the electrolyte-coupled polarization in VRFB dramatically decreased upon modification of carbon felt electrode surface. It is also demonstrated that the compressibility of carbon felt electrodes was important to the VRFB polarization, which are concerned with mass transfer polarization. The impedance analysis will be helpful for obtaining better and longer-lived VRFB performances.

• 한국응용과학기술학회지
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• 제26권2호
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• pp.132-142
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• 2009

The benzophenone derivatives(4-$CH_3O$-4'-$NO_2$ and 3,4'-di-$NO_2$) are synthesized by the Fridel-Craft acylation and the nitration method. Electrochemical redox potentials of the benzophenone derivatives (4-$CH_3O$, H, 3-Cl, 3-$NO_2$, 4-$NO_2$, 4-$CH_3O$-4'-$NO_2$, 3,4'-di-$NO_2$) are measured by using cyclic voltammometry. In the relationship of summing Hammett value and redox potential, we find a proportional constant$(\rho)$ that shows a good relation with an electrochemical property and a reactivity of the benzophenone derivatives. The benzophenone substituted with the electron donating groups(4-$OCH_3$ and 4-$OCH_3-4'-NO_2$) are higher the energy in the LUMO level, then increasing a band-gap energy$(E_g)$, their $E_gs$ are obtained as a 3.94 eV and 3.59 eV, respectively.

• Journal of Microbiology
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• 제39권3호
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• pp.149-153
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• 2001

The electron transfer reaction is one of the most essential processes of life. Not only does it provide the means of transforming solar and chemical energy into a utilizable form for all living organisms, it also extends into a range of metabolic processes that support the life of a cell. Thus, it is of great interest to understand the physical basis of the rates and reduction potentials of these reactions. To identify the major determinants of reduction potentials in redox proteins, we have chosen the simplest electron transfer protein, rubredoxin, a small (52-54 residue) iron-sulfur protein family, widely distributed in bacteria and archaea. Rubredoxins can be grouped into two classes based on the correlation of their reduction potentials with the identity of residue 44; those with Ala44 (ex: Pyrococcus furiosus) have reduction potentials that are ∼50 mV higher than those with Va144 (ex: Clostridium pasteurianum). Based on the crystal structures of rubredoxins from C. pasteurianum and P. furiosus, we propose the identity of residue 44 alone determines the reduction potential by the orientation of the electric dipole moment of the peptide bond between 43 and 44. Based on 1.5 $\AA$ resolution crystal structures and molecular dynamics simulations of oxidized and reduced rubredoxins from C. pasteurianum, the structural rearrangements upon reduction suggest specific mechanisms by which electron transfer reactions of rubredoxin should be facilitated.

• 전기화학회지
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• 제7권4호
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• pp.167-172
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• 2004

3,4-dihydroxybenzaldehyde(3,4-DHB) was oxidatively el electropolymerized on glassy carbon (GC) electrodes to prepare CC/p-3,4-DHB type electrodes, which were subsequently modified with 3,4-dihydroxybenzoic acid(3,4-DHBA) using 0.05M HCI as a catalyst. The esterification reactions were performed between -OH sites on the polymeric film surface of the p-3,4-DHB and the -COOH sites within the 3,4-DHBA molecules in solution. These reactions had a rate constant value of $1.1\times10^{-1}\;s^{-1}$ for the esterification step as obtained from the first-order rate constant in the solution. The electrochemical responses of the GC/p-3,4-DHB-3,4-DHBA electrodes exert an influence upon the buffer solution, its pH and applied potential ranges. The redox process of the electrode was more easily controlled by charge transfer kinetics than that of the CC/p-3,4-DHB. The modified electrodes had redox active sites that were 10 times more active than those present before modification. The electrical admittance of the modified electrodes was also three times higher than that of the unmodified electrodes. After being annealed in ethanol for 20 hrs the electrodes brought about a 3.3 times greater change of water molecules in the redox reaction. The modified electrodes are stable in the potential range of 0.4 to 0.55V.

• 한국전기전자재료학회:학술대회논문집
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• 한국전기전자재료학회 1999년도 춘계학술대회 논문집
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• pp.357-361
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• 1999

GOD electrochemically immobilized in PPy/GOD complex have an effect on redox properties of the complex. In the cyclicvoltammetry, GOD shows the redox reaction at the potential below -0.6Y vs. Ag/AgCI. That leads to new peaks in the cyclicvoltammograms in additional to typical PPy peaks. The pH of electrolyte solution during potential swing decreased to 4.4, and then increased to 10. That suggests the redox of GOD for the cycling. As the concentration of GOD was increased, the anodic wave of the new peaks was strong as much as increased. GOD obstructs the diffusion of electrolyte anion because of its net chain. Insulating property of GOD is cause that it made the faradic impedance of complex large in charge transfer. It suggests that increase of the concentration of GOD be against electrochemical coupling. Therefore, the concentration of GOD and electrochemical coupling should be dealt with each other. The apparent Michaelis-lenten constant ( K\`$_{M}$ ) was determined by 30.7 mmol d $m^{-3}$ fur the PPy/GOD complex. The value is of the same order of magnitude as that for soluble glucose oxidase from Aspergillus Niger.r.