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2019 Vol.24, Issue 4 Preview Page

Article

The Spatial and Vertical Variations of Metal Pollution in Sediments after Tidal Power Plant Operation in Shihwa Lake

시화호 조력발전소 가동으로 인한 퇴적물 내 중금속 오염 특성 변화

JIHYUN LEE12
,
HYERYEONG JEONG12
,
JIN YOUNG CHOI12
,
KONGTAE RA12*
이 지현12
,
정 혜령12
,
최 진영12
,
나 공태12*
1Marine Environmental Research Center, Korea Institute of Ocean Science & Technology (KIOST)
2Department of Ocean Science (Oceanography), KIOST School, Korea University of Science & Technology (UST)
1한국해양과학기술원 해양환경연구센터
2과학기술연합대학원대학교 한국해양과학기술원 스쿨 해양과학(해양학)
* Corresponding Author
30 November 2019. pp. 535-547
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Abstract

본 연구에서는 조력발전소 가동 이후 퇴적물 내 공간적 중금속 오염변화 특성을 알아보기 위하여, 2015년 표층퇴적물, 퇴적물 코어, 입자성 침강물질 내 중금속 농도를 분석하고 가동 이전인 2009년과의 비교를 실시하였다. 2015년에 채취한 표층퇴적물 내 중금속의 평균 농도는 조력발전소 가동 이전인 2009년에 비해 8% (Cd)~31% (Zn, Hg) 감소하였다. 본 연구에서 분석된 8개 원소를 모두 포함한 오염부하지수(PLI)를 계산한 결과, 2015년 자료가 2009년에 비해 중금속 오염도가 18% 감소하였다. 하지만 2015년에도 산업단지에 인접한 상류지역에서는 여전히 Cu, Zn, Pb가 주의기준(TEL)을 초과하였다. 조력발전소 가동 이전에 비해 2015년 중금속에 오염된 퇴적 깊이는 S6 정점에서는 15 cm, S7 정점에서는 12 cm 증가하였으나 중금속의 평균농도는 감소하였다. 입자물질의 총 침강속의 평균은 2009년에 32.5 g/m2/d에서 2015년 103.5 g/m2/d로 입자의 침강량이 3.2배 높아졌다. 수층의 입자물질 증가는 조력발전소 가동에 따라 저층 퇴적물이 재부유된 것으로 판단된다. 코어 시료에서 오염 퇴적 깊이와 입자물질의 침강속 증가는 조력발전소 가동으로 인해 발생한 해류의 영향으로 저층 퇴적물이 재부유되어 다른 지역으로 이동/퇴적된 사실을 나타내고 있다. 표층퇴적물과 마찬가지로 상류지역 코어에서는 여전히 Cr, Cu, Zn, Pb, Cd이 주의기준을 초과하고 있었으며, 중금속 오염 퇴적물이 40 cm 이상 축적되어 있어 여전히 산업단지를 통한 중금속 오염이 심각한 것으로 나타났다. 조력발전소 가동에 의한 해수 유통량의 증가로 시화호 중금속 오염은 다소 감소하였으나, 산업활동을 통한 중금속의 오염은 여전히 존재하고 있으며 퇴적물 재이동을 통해 오염된 퇴적물이 시화호 외측으로 방류되어 환경 혹은 생태계에 악영향을 미칠 가능성이 있다. 따라서 금속 안정동위원소를 활용한 오염원 추적과 같은 과학적 조사와 오염원을 줄이기 위한 정책적인 결단이 필요한 것으로 판단된다.

In this study, the heavy metal analysis in sediments (surface sediments, sediments cores and settling particles) from Shihwa Lake has been carried out to evaluate the changes of metal pollution levels in sediments after the operation of Tidal Power Plant (TPP). The average concentrations of metals in surface sediments sampled in 2015 were 8% (Cd)~31% (Zn, Hg) lower than in 2009 before TPP operation. Results of calculating the pollution load index (PLI) with 8 metals, the PLI value in 2015 showed a 18% decrease compared to 2009. However, Cu, Zn, Pb concentrations of surface sediments in 2015 at the upper region around industrial complex still exceeded the TEL (threshold effect level) values for sediment quality guideline in Korea. After the operation of TPP, the metal contaminated depths were increasing from 15 cm to 30 cm at S6 site and from 8 cm to 20 cm at S7 site, respectively. Our data showed that the mean concentration of heavy metals in core samples decreased but the contaminated depth increased. The average of the total sedimentation flux for particulate matter increased by 3.2 times from 32.5 g/m2/d in 2009 to 103.5 g/m2/d in 2015. This showed that the bottom sediments were resuspended by the operation of TPP, resulting in an increase of particulate matter in the water column. These results suggest that the sediments contaminated with heavy metals seem to be resuspended and relocated due to the water current caused by the operation of TPP. Cr, Cu, Zn, Pb and Cd were highly exceeding the TEL values in the upstream region and accumulated more than 40 cm of sediment depth, indicating that heavy metal contamination through industrial activity were still a serious environmental problem of Shihwa Lake. Although the metal pollution of Shihwa Lake has been slightly reduced, the contaminated sediments with heavy metals inside of Shihwa Lake might be discharged to outer sea after the resuspension by TPP operation. It is necessary for the advanced scientific approach and political decision to drastically reduce the heavy metal pollution of the study region.

Keywords
Heavy metal
Pollution
Sediments
Settling particle
Tidal power plant

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Information
  • Publisher :The Korean Society of Oceanography
  • Publisher(Ko) :한국해양학회
  • Journal Title :The Sea Journal of the Korean Society of Oceanography
  • Journal Title(Ko) :한국해양학회지 바다
  • Volume : 24
  • No :4
  • Pages :535-547
  • Received Date : 2019-09-25
  • Revised Date : 2019-10-23
  • Accepted Date : 2019-10-25
  • DOI :https://doi.org/10.7850/jkso.2019.24.4.535
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