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다양한 위해성평가 방법에 따라 도출한 토양오염 판정기준의 차이에 관한 연구(III): 우리나라 납 오염 위해성평가 방법 제안
정재웅,남경필,Jung, Jae-Woong,Nam, Kyoungphile 한국지하수토양환경학회 2015 지하수토양환경 Vol.20 No.6
The most critical health effect of lead exposure is the neurodevelopmental effect to children caused by the increased blood lead level. Therefore, the endpoint of the risk assessment for lead-contaminated sites should be set at the blood lead level of children. In foreign countries, the risk assessment for lead-contaminated sites is conducted by estimating the increased blood lead level of children via oral intake and/or inhalation (United States Environmental Protection Agency, USEPA), or by comparing the estimated oral dose to the threshold oral dose of lead, which is derived from the permissible blood lead level of children (Dutch National Institute for Public Health and the Environment, RIVM). For the risk assessment, USEPA employs Integrated-Exposure-Uptake-Biokinetic (IEUBK) Model to check whether the estimated portion of children whose blood lead level exceeds 10 μg/dL, threshold blood lead level determined by USEPA, is higher than 5%, while Dutch RIVM compares the estimated oral dose of lead to the threshold oral dose (2.8 μg/kg-day), which is derived from the permissible blood lead level of children. In Korea, like The Netherlands, risk assessment for lead-contaminated sites is conducted by comparing the estimated oral dose to the threshold oral dose; however, because the threshold oral dose listed in Korean risk assessment guidance is an unidentified value, it is recommended to revise the existing threshold oral dose described in Korean risk assessment guidance. And, if significant lead exposure via inhalation is suspected, it is useful to employ IEUBK Model to derive the risk posed via multimedia exposure (i.e., both oral ingestion and inhalation).
제일인산칼륨과 벤토나이트 처리를 통한 토양 내 TNT와 중금속 이동성 및 인체위해도 저감 기술
정재웅,유기현,남경필,Jung, Jae-Woong,Yu, Gihyeon,Nam, Kyoungphile 한국지하수토양환경학회 2015 지하수토양환경 Vol.20 No.6
Simultaneous mobility reduction of explosives and heavy metals in an operational range by monopotassium phosphate (MKP) and bentonite spreading technology was investigated. Potassium ion and phosphate ion in MKP act as explosives sorption enhancer and insoluble heavy metal phosphate formation, respectively, while bentonite acts as the explosives adsorbent. Then, the decrease in surface water concentration of the pollutants and resulting risk reduction for local residents of the operational range, by MKP/bentonite application was estimated. Under untreated scenario, the noncancer hazard index (HI) exceeded unity on February, July and August, mainly due to 2,4,6-trinitrotoluene (TNT); however, MKP/bentonite treatment was expected to lower the noncancer hazard index by decreasing the surface water concentration of explosives and heavy metals (especially TNT). For example, on July, estimated surface water concentration and HI of TNT were 0.01 mg/L and 1.1, respectively, meanwhile the sorption coefficient of TNT was 3.9 mg<sup>1−n</sup>kg<sup>−1</sup>L<sup>n</sup>. However, by MKP/bentonite treatment, the TNT sorption coefficient increased to 113.8 mg<sup>1−n</sup>kg<sup>−1</sup>L<sup>n</sup> and the surface water concentration and HI decreased to about 0.002 mg/L and 0.2, respectively. Based on the result, it can be concluded that MKP/bentonite spreading is a benign technology that can mitigate the risk posed by the pollutants migration from operational ranges.
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.
화약류 및 중금속의 인체위해성평가 및 생태독성에 기반한 토양허용농도도출에 관한 연구
김문경,정재웅,남경필,정슬기,Kim, Moonkyung,Jung, Jae-Woong,Nam, Kyoungphile,Jeong, Seulki 한국지하수토양환경학회 2015 지하수토양환경 Vol.20 No.6
Permissible soil concentrations for explosives (i.e., TNT and RDX) and heavy metals (i.e., Cu, Zn, Pb, and As) heve been derived from human risk and ecotoxicity, respectively. For TNT and RDX, human risk based-permissible soil concentrations were determined as 460 mg-TNT/kg-soil and 260 mg-RDX/kg-soil. Ecotoxicity based-permissible soil concentrations for Cu and Zn were determined from species sensitivity distribution (SSD) and uncertainty factor of 1 to 5, yielding 18.0-40.0 mg-Cu/kg-soil and 46.0-100 mg-Zn/kg-soil. For Pb and As, ecotoxicity data were not enough to establish SSD so that a deterministic method was used, generating 13.8-30.8 mg-Pb/kg-soil and 2.10-4.60 mg-As/kg-soil. It is worth noting that the methodology used to derive permissible concentrations in soil can differ depending on ecotoxicity data availability and socio-economic situations, which results in different permissible concentrations. The permissible concentrations presented in this study have been derived from conservative assumptions for exposure parameters, and thus should be considered as soil standards. In the light of remediation and pollution management of a site of interest, the site-specific and receptor-specific permissible soil concentrations should be derived considering potential receptors, current and future land use, background concentrations, and socio-economic consultation.