토양 경작법을 이용한 유류오염토양 정화사업 타당성 연구

조은혜,류혜림,신도연,김영진,최용주,남경필,Jho, Eun Hea,Ryu, Hyerim,Shin, Doyun,Kim, Young-Jin,Choi, Yong Ju,Nam, Kyoungphile 한국지하수토양환경학회 2013 지하수토양환경 Vol.18 No.2

The landfarming treatment for the remediation of the petroleum contaminated soil at the returned U.S. Military bases was investigated in this study. Specifically, the bioaugmentation performance using various commercially available petroleum-degrading bacteria was evaluated and the directions for enhancing the performance of the landfarming treatment were suggested. The environmental factors of the soils at the returned U.S. Military bases chosen for remediation indicate that the landfarming treatment can be used as the remediation technique; however, the addition of nitrogen or phosphorus is required. The lab-scale landfarming treatment tests using the model soil and the site soil showed that the degradation efficiency was greater with the model soil than the site soil and that the treatment performance was not affected by the number of bacteria present in the soil in the range of $10^6-10^{12}$ CFU/g. These results suggest that the successful landfarming treatment depends on the petroleum degradability of bacteria used and the environmental conditions during the treatment rather than the number of petroleum-degrading bacteria used.

싱가포르 오염준설토 정화 후 생태 독성 변화

조은혜,윤성호,황선경,이성종,김홍석,채희훈,Jho, Eun Hea,Yun, Seong Ho,Hwang, Sun Kyung,Lee, Sung Jong,Kim, Hongseok,Chae, Heehun 한국지하수토양환경학회 2017 지하수토양환경 Vol.22 No.5

Contaminated sediment can be treated in order to reuse the treated sediment. Even though the chemical criteria are satisfied, the treated sediment could still impose toxic effects. Therefore, this study investigated the changes in the ecological toxic effects of the contaminated sediment from the J region in Singapore after treatment. The contaminated sediment was subject to sequential soil washing and thermal treatment, followed by pH neutralization. Toxic effects of the contaminated and treated sediments were determined by using Vibrio fischeri ($Microtox^{(R)}$), Triticum aestivum (wheat), and Eisenia foetida (earthworm). After treatment, the concentrations of total petroleum hydrocarbons and heavy metals were decreased by 98% and 59-93%, respectively, and satisfied the Industrial Maximum Values of the Dutch Standard, which were used as the remedial goal. The bioluminescence reduction of V. fischeri decreased significantly, and the earthworm survival increased from 0% to 90% after treatment. The germination rate increased from $0{\pm}0%$ to $75{\pm}13%$ after treatment, but the treated sediment may need additional treatment such as nutrient addition for better plant growth. Overall, this study showed that the treatment of the contaminated sediment satisfactorily removed mixed contaminants, and this led to reduction in toxic effects, suggesting improved potentials for reuse of the treated sediment.

미세플라스틱의 중금속 흡착 능력 연구

조은혜(Eun Hea Jho),김수현(Su Hyun Kim),전어진(Eo Jin Jeon),안세인(?Se In Ahn),문영진(Young Jin Mun),조찬희(Chan Hee Cho),김영홍(Yeonghong Kim),주원정(Won Jung Ju) 대한환경공학회 2020 대한환경공학회 학술발표논문집 Vol.2020 No.11

토양 중 탄산무수화효소 보유 박테리아를 위한 프라이머 개발

조은혜(Eun Hea Jho),홍진경(Jin-Kyung Hong),양동진(Dong Jin Yang) 대한지질학회 2020 대한지질학회 학술대회 Vol.2020 No.10

갈바닉 산화와 황철석 용해를 이용한 친환경 원위치 광미 무해화 기술

주원정,조은혜,남경필,Ju, Won Jung,Jho, Eun Hea,Nam, Kyoungphile 응용생태공학회 2016 Ecology and resilient infrastructure Vol.3 No.4

선광 및 제련과 같은 광산활동 과정에 발생하는 광미는 고농도의 중금속을 함유하고 있고, 그 중 황철석을 함유한 광미는 광산주변 수계 및 토양 오염의 주요 원인이다. 이러한 황철석을 함유한 광미의 무해화를 위해 화학전지 (연료전지)의 개념을 활용할 수 있다. 화학전지에서 황철석의 자발적인 산화, 즉, 갈바닉 산화를 통해 황철석이 용해되면서 $Fe^{3+}$와 황산이 생성되어 pH가 감소하게 된다. 이는 황철석 함유 광미 내 중금속의 용출 촉진 효과를 가져올 수 있다. 본 연구에서는 $23^{\circ}C$ 조건에서 4주 간 산성용액과 갈바닉 반응기를 이용해 황철석을 처리하며 총 용존 철 농도와 용액의 pH를 확인하였다. 또한 주사전자현미경을 이용해 처리 후 황철석 표면을 관찰하였다. 갈바닉 반응기를 이용한 황철석의 용해가 산성용액을 이용한 황철석의 용해에 비해 약 2.9배 높은 총 철을 용출시킨 것을 확인하였고, pH 저감 효과도 더 큰 것을 확인하였다. 또한 표면 분석 결과 갈바닉 반응기 내에서 반응한 황철석의 표면에서 더 많은 홈을 발견되었다. 본 연구를 통해 갈바닉 산화에 의해 황철석의 용해가 촉진된 것을 확인하였으며, 갈바닉 산화가 황철석 함유 광미의 무해화 기술로 사용될 수 있는 가능성을 확인하였다. Mine tailings generated during mining activity often contain high concentrations of heavy metals, with pyrite-containing mine tailings in particular being a major cause of environmental problems in mining areas. Chemical cell technology, or fuel cell technology, can be applied to leach heavy metals in pyrite-containing mine tailings. As pyrite dissolves through spontaneous oxidation (i.e. galvanic oxidation) in the anode compartment of the cell, $Fe^{3+}$, sulfuric acid are generated. A decrease in pH due to the generation of sulfuric acid allows heavy metals to be leached from pyrite-containing mine tailings. In this study, pyrite was dissolved for 4 weeks at $23^{\circ}C$ in an acidic solution (pH 2) and in a galvanic reactor, which induces galvanic oxidation, and total Fe leached from pyrite and pH were compared in order to investigate if galvanic oxidation can facilitate pyrite oxidation. The change in the pyrite surface was analyzed using a scanning electron microscope (SEM). Comparing the total Fe leached from the pyrite, there were 2.9 times more dissolution of pyrite in the galvanic reactor than in the acidic solution, and thus pH was lower in the galvanic reactor than in the acidic solution. Through SEM analysis of the pyrite that reacted in the galvanic reactor, linear-shaped cracks were observed on the surface of the pyrite. The study results show that pyrite dissolution was facilitated through the galvanic oxidation in the galvanic reactor, and also implied that the galvanic oxidation can be one remediation option for pyrite-containing mine tailings.

생태학적 기능을 이용한 광미 활용 전기 생산: 철산화박테리아를 이용한 황철석 산화 속도 증진을 통한 전류 밀도 향상 가능성 평가

주원정,조은혜,남경필,Ju, Won Jung,Jho, Eun Hea,Nam, Kyoungphile 응용생태공학회 2014 Ecology and resilient infrastructure Vol.1 No.1

본 연구는 광산 지역 토착미생물인 철산화박테리아 (Acidithiobacillus ferrooxidans)를 이용하여 산성광산배수의 원인물질인 황철석을 함유한 광미로부터 전기를 생산하고자 하는 목적으로 수행되고 있다. 예비실험으로서 철산화박테리아의 존재 여부가 배양액 내 $Fe^{2+}$과 총 철의 농도 변화에 미치는 영향을 관찰하였다. 철산화박테리아가 존재하지 않는 조건에서는 초기 9,000 mg/L의 $Fe^{2+}$이 약 6,000 mg/L까지 감소하였으나, 철산화박테리아가 존재하는 조건에서는 약 400 mg/L까지 감소하였다. 이는 철산화박테리아가 $Fe^{2+}$의 산화를 촉진하기 때문으로, 황철석을 활용한 연료전지에 철산화박테리아를 적용하면 $Fe^{2+}$의 산화 과정에서 생기는 전자의 이동이 증가하여 전지의 전류 밀도를 높일 수 있는 가능성을 보여준다. 본 연구는 광산 지역 토착미생물의 생태학적 기능을 활용해 광미로부터 전기를 생산해내는 기술을 개발하는 연구의 바탕을 마련한다는 점에서 의미 있다. The research evaluates the possibility of generating electricity using pyrite containing mine tailings, which are the major cause of acid mine drainage (AMD), by applying iron oxidizing bacteria (in this case, Acidithiobacillus ferrooxidans) and chemical fuel cell technology. The changes in the aqueous $Fe^{2+}$ concentration, which can represent an ionized form of pyrite, with an initial concentration of 9,000 mg/L were investigated during the 20 d growth period. Both the $Fe^{2+}$ and total iron (i.e., total $Fe^{2+}$)concentrations with or without A. ferrooxidans were observed. The $Fe^{2+}$ concentration decreased to about 6,000 mg/L, in the abiotic condition, while it decreased to about 400 mg/L in the biotic condition. The results showed that the increased $Fe^{2+}$ oxidation in the presence of A. ferrooxidans (i.e., catalytic ability of A. ferrooxidans) can be applied to electricity generation using pyrite containing mine tailings. In the co-presence of A. ferrooxidans and pyrite containing mine tailings, $Fe^{2+}$ oxidation and hence electron production increases, which, in turn, improves current density. This study can be applied to utilize ecological functions of indigenous bacteria in mine areas to enhance electricity generation efficiency.

황철석과 토착미생물이 광미를 활용한 전기 생산에 미치는 영향

주원정,조은혜,남경필,Ju, Won Jung,Jho, Eun Hea,Nam, Kyoungphile 응용생태공학회 2015 Ecology and resilient infrastructure Vol.2 No.1

본 연구는 산성광산배수를 유발하는 광미를 연료전지 기술에 적용하여 유용하게 활용할 수 있는지 알아보기 위해 수행하였다. 황철석 성분을 함유한 광미와 철산화를 촉진하기 위한 철산화균을 포함한 토착세균을 사용하여 미생물연료전지를 구성하여, 광미 내 황철석 함량이 높을수록 연료전지의 전기적 효율이 향상됨을 확인하였다. 또한, 광미를 활용한 연료전지에서 토착세균 주입을 통해 전류밀도와 전력밀도를 각각 3배, 10배 정도 향상시켜, 철산화에 관여하는 미생물의 주입이 광미를 이용한 연료전지 효율 향상에 도움이 됨을 확인하였다. 본 연구는 광산 지역 토착세균의 생태학적 기능을 연료전지 기술과 활용해 광미로부터 오염유발 우려물질을 저감함과 동시에 전기 생산이 가능함을 확인하여, 광미를 활용한 미생물연료전지 기술이 광미의 무해화 및 전기 생산을 위한 기술로 사용될 수 있음을 보여준다. Acid mine drainage (AMD) producing mine tailings can be beneficially recycled to generate electricity by applying fuel cell technology. Pyrite-containing mine tailings and indigenous bacteria from abandoned mine areas were used to construct fuel cells to investigate the effect of pyrite contents and the presence of iron-oxidizing bacteria. The results showed an enhanced electrical performance with a higher content of pyrite in mine tailings. The inoculation of the indigenous bacteria also enhanced the current density by about three times, and the power density by about 10 times. Overall, this study shows that the combined use of the ecological function of indigenous bacteria from mine areas and mine-tailings in fuel cells does not only contribute to reducing harmful effects of mine tailings but also generate electricity.

비소 오염기간이 토양 내 비소의 존재형태와 식물독성에 미치는 영향

양우진,조은혜,임진우,정슬기,남경필,Yang, Woojin,Jho, Eun Hea,Im, Jinwoo,Jeong, Seulki,Nam, Kyoungphile 한국지하수토양환경학회 2016 지하수토양환경 Vol.21 No.3

This study investigates effects of an aging period on arsenic (As) chemical forms in soils and phytotoxicity using artificially As-contaminated soils with a range of As concentrations (0-300 mg/kg) and aging periods (0 and 3 months). A sequential extraction procedure showed that the increasing As concentration in soils increased the ratio of non-specifically and specifically bound As, which are known to be bioavailable. This resulted in increasing As uptake by tomatoes with increasing As concentration (R²=0.87 for exponential fitting); however, the seed germination was not sensitive to the As concentrations of the soil samples. The seed germination was also statistically similar in the soils with 75 and 150 mg-As/kg regardless of the aging period. The time taken until the seed germination (i.e., lag phase), on the other hand, decreased from 10 d to 3 d with aging for 3 months. This can be attributed to the decreased amount of bioavailable As with aging. Overall, this study shows that when the toxic effects of the As-contaminated soils are assessed using tomato plants, it is better to use more sensitive methods than seed germination such as the As accumulation or the lag phase for seed germination.

수계 내 테트라사이클린, 설파다이아졸, 트리톤 X-100 혼합물의 광분해

윤성호,이성종,조은혜,문준관,Yun, Seong Ho,Lee, Sungjong,Jho, Eun Hea,Moon, Joon-Kwan 한국환경농학회 2021 한국환경농학회지 Vol.40 No.1

BACKGROUND: Chemicals such as antibiotics and surfactants can enter agricultural environment and they can be degraded by natural processes such as photolysis. These chemicals exist in mixtures in the environment, but studies on degradation of the mixtures are limited. This study compares the photodegradation of Triton X-100 (TX) and antibiotics [tetracycline (TC) and sulfathiazole (STH)] when they are in a single solution or in mixtures. METHODS AND RESULTS: TC, STH, and TX solutions were exposed to UV-A for the photodegradation tests for 14 days. The residual TC, STH, and TX concentrations were analyzed by using HPLC. The TC degradation was similar regardless of the presence of TX, while the TX degradation was lower in the presence of TC. The STH degradation was similar regardless of the presence of TX, while the TX degradation was greater in the presence of STH. However, the STH degradation was slower in the TC-STH-TX mixture than in the STH-TX mixture. Also, the TX degradation was negligible in the TC-STH-TX mixture. The results show that the photodegradation of TC, STH, and TX can be different in mixtures. This can be attributed to the different emission and absorption wavelengths of each compound and interaction between these compounds and photoproducts. CONCLUSION: Overall, this study emphasizes that photodegradation of single chemicals and chemical mixtures can be different, and more studies on single compounds as well as mixtures are required to understand the fate of chemicals in the environment in order to manage them properly.

수경재배 배양액 종류가 상추 성장에 미치는 영향

김가은(Ga Eun Kim),조은혜(Eun Hea Jho),김진황(Jin Hwang Kim),허정민(Jeong Min Heo) 대한환경공학회 2021 대한환경공학회 학술발표논문집 Vol.2021 No.11