• 자원환경지질
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• 제44권6호
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• pp.475-483
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• 2011

자유낙하식 망간단괴 채취기 (FFG)는 정점의 해저면에 분포하는 망간단괴를 모두 채취하기 어렵기 때문에 망간단괴의 부존률을 평가할 때 반드시 보정해서 사용해야 한다. 북동태평양에 위치한 대한민국의 망간단괴 광구 중에서 북쪽광구의 보정상수는 이미 해저면 영상분석으로 결정되어 있다. 그러나 남쪽광구는 망간단괴가 퇴적물에 피복되어 있어서 영상분석에의한 부존률 평가에 지장을 받을 가능성이 있다. 이번 연구에서는 과거에 남쪽광구에서 FFG로 획득한 부존률 자료에 사용한 보정상수를 검증하기 위하여 2007~2009년에 상자형 시료 채취기와 FFG를 동시에 운영하여 40개의 정점자료를 획득하였다. BC와 FFG의 상관분석을 통하여 BC가 FFG에 비하여 1.43배 부존률이 크게 나타났으며, 이것은 남쪽광구에서 실제 망간단괴 분포를 평가하기 위해서는 FFG 자료에 1.43의 보정상수를 곱해서 사용해야 되는 것을 의미한다. 이번에 획득한 보정상수는 기존에 영상분석을 통해 얻은 보정상수(1.42~1.45)와 유사한 결과로서 남쪽광구에서 사용할 보정상수가 검증되었다고 판단된다.

• Ocean and Polar Research
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• 제32권4호
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• pp.475-482
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• 2010

Hydrothermal deposits on deep-sea floors are expected to provide potential metal resources for future demands. Korea was recently granted a prospecting licence to undertake exploration for hydrothermal metal deposits in the exclusive economic zone (EEZ) of the Kingdom of Tonga in the Pacific Ocean. The Korean Deep Seabed Mining Group (KDSMG), which consists of four Korean companies involved in marine technologies, oil and gas shipping, and smelter industries, has conducted research to evaluate the region's resource potential in cooperation with the Ministry of Land, Transport and Maritime Affairs (MLTM) of Korea. Here we present and reflect on the exploration results of these companies and their strategic plans. We also evaluate Research and Development (R&D) progress for the commercial development of seafloor hydrothermal deposits. Our own strategies and prospects for the commercial development of this potential resource are also outlined. We do acknowledge that other potentially important information regarding the amount of ore body, the inside structure, and the metal yields have not yet been clarified sufficiently. As such it is necessary to address these problems through experimental R&D and surveys.

• 한국지구물리탐사학회:학술대회논문집
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• 한국지구물리탐사학회 2009년도 학술대회 초록집
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• pp.139-143
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• 2009

• 자원환경지질
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• 제29권4호
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• pp.429-437
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• 1996

The purpose of this study is to correct the nodule abundance of FFG (Free Fall Grab) sampler on KODOS (Korea Deep Ocean Study) area in North-East Pacific Ocean. The image analysis of sea-floor photography was carried out for correcting the abundance of nodules, and the image enhancement techniques and edge detection method were used to discriminate between nodules and sediments. The trace of nodules on sediments was detected to reduce the fractionation effect in calculating the coverage of nodules. The three methods, using the coverage of nodules, using the volume density, and using corrected volume density, were utilized for the correction of the nodule abundance. The method using the coverage of nodules was more convenient and available for the correction of nodule abundance than the other two methods. The method using the corrected volume density had the highest confidence level compared with the other methods.

• Ocean and Polar Research
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• 제28권4호
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• pp.475-484
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• 2006

In order to reveal the vertical variation of physical properties in deep-sea sediments, deep-sea sediment cores were collected at 78 stations using a multiple corer in the KR5 area, one of the Korea contract areas for manganese nodule exploration, located in the northeast equatorial Pacific. Based on the color of sediments, sampled sediment cores were characterized into three lithologic units (unit 1,2, and 3). In all sediment cores, three units appear systematically; unit 1 lies at the top of cores and unit 2 and/or unit 3 appear to underlie unit 1 or alternate with unit 3. Unit 1 layer from the top of cores shows dark grayish brown to dark brown with mean thickness of 10.2cm. Unit 2 and 3 layers show very dark brown to black color and yellowish brown to brown color, respectively. According to the physical properties of the deep-sea sediment cores, sediment column can be divided into three sections. Section A $(0{\sim}15cm)$ in subbottom depth consists mostly of unit 1. Mean values of physical properties of section B $(15{\sim}30cm)$ in subbottom depth are similar to those of section C (>30 cm) in subbottom depth. However, the physical properties of section B were more variable than those of section C because of the high activity of bioturbation in section B. These results will provide valuable information for selecting suitable sites for mining manganese nodules in the Korea contract areas.

• 지구물리와물리탐사
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• 제14권4호
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• pp.298-304
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• 2011

한국해양연구원에서는 2011년 4월에 쇄빙선 아라온호, Oceaneering사의 ROV (Remotely Operated Vehicle) 및 삼성분자력계(Three component vector magnetometer)를 이용하여 남서태평양 라우분지에 위치한 TA25해산 칼데라 서측 사면에 대하여 심해자력탐사를 실시하였다. 연구지역은 약 900 m ~ 1200 m의 수심대역을 보인다. 이 심해탐사를 위하여 국내 최초로 3000 m급 심해 삼성분자력계를 제작하였다. 자력계센서부분은 ROV의 상부에, 자력계로거부분은 ROV의 하부에 장착하였으며, ROV는 ROV의 정확한 위치를 알려주는 USBL (Ultra Short Base Line)과 고도계를 이용하여 정해진 측선을 따라 해저면에서 약 25 ~ 30 m의 수직 간격을 유지하며 이동하였다. 삼성분자력계는 자기장의 X(북쪽성분), Y(동쪽성분)과 Z(수직성분)의 벡터성분을 측정하므로 모션센서를 이용하여 ROV의 움직임(피치, 롤, 요)에 대한 보정을 실시하였다. 자력센서자료와 모션센서자료는 ROV의 광케이블과 아라온호의 네트워크를 이용하여 노트북에 저장되며 ROV의 정확한 위치자료인 USBL자료는 후처리를 통하여 병합하였다. 이렇게 획득한 심해 삼성분자력자료는 조사지역의 유망한 열수광상을 유추하는데 유용하게 활용될 것으로 판단된다.

• 지구물리와물리탐사
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• 제10권3호
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• pp.173-182
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• 2007

북동태평양 클라리온-클리퍼톤 균열대 지역의 해저평원에는 여러 유용 금속을 함유한 망간단괴가 다량 분포하는 것으로 알려져 있다. 심해저카메라(DSC)를 이용하여 지형과 단괴 부존량과의 상관관계를 제시하는 연구 결과마다 단괴 생산 유망 지역의 단괴부존량과 지형과의 관계를 다르게 설명하고 있다. 또한, 수중에 위치하는 DSC 위치추정 방법론에 대한 정확한 근거가 명확하게 제시되지 않았다. 북동태평양 대한민국 심해연구(KODOS) 지역에서 현장탐사를 수행하여 지형에 따른 단괴 채광조건의 변화를 관찰하였다. 이 연구에서는 망간단괴 분포 경향 및 채광가능지역을 분석하고자 할 때, DSC를 이용한 근접 해저면 영상관찰 방법의 활용가능성을 제시하고자 하였다. 이를 위해 해저산이 없는 심해평원지역인 KODOS 지역의 남쪽구역($132^{\circ}10'W$, $9^{\circ}45'N$ 부근)에서 DSC 영상으로부터 단괴 부존량을 추출하고 다중빔음향측심기를 사용하여 해저면 수심 변화를 동시에 측정하였다. 또한, DSC 수중 위치추정의 정확성을 제고하고자, DSC 위치 계산 방식에 적절한 가정을 도입하였고, DSC 측선의 교차점에서 측정한 부존량을 이용하여 간접적으로 위치 추정의 정확도를 검증하였다. DSC 영상을 관찰하면 단괴 및 퇴적물뿐만 아니라 해저면의 함몰지역인 균열대를 다수 발견할 수 있다. 또한, DSC 영상을 통해 관찰된 해저 균열대의 발견시간 자료로 부터 채광 장애지역으로 예상되는 균열대의 위치 추정을 시도하였다. 분석 결과 채광장비가 주행할 수 없는 채광 장애지역은 해저사면과 해저구릉지역임을 확인할 수 있었다.

• 한국해양공학회지
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• 제30권5호
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• pp.389-399
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• 2016

This paper presents the explorations of hydrothermal vents located in the Marina Arc and Back Arc Basin using the deep-sea ROV Hemire. These explorations were conducted by KRISO and KIOST to demonstrate the capability of Hemire in various applications for deep-sea scientific research. The missions included the following: (1) to search the reported vents, (2) conduct visual inspections, (3) deploy/recover a sediment trap and bait traps, (4) sample sediment/water/rock, (5) measure the magnetic field at the vent site, and (6) acquire a detailed map using multi-beam sonar near the bottom. We installed three HD cameras for precise visual inspection, a high-temperature thermometer, a three-component magnetometer, and a multi-beam sonar to acquire details of the bottom contour or identify vents in the survey area. The explorations were performed in an expedition from March 23 to April 5, 2016, and the missions were successfully completed. This paper discusses the operational process, navigation, and control of Hemire, as well as the exploration results.

• Ocean and Polar Research
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• 제37권1호
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• pp.81-90
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• 2015

International Seabed Authority (ISA) is currently developing rules with regard to exploitation of manganese nodules which will be contained in its first regulations governing the exploitation of deep seabed mineral resources. A stakeholder survey was conducted in the early 2014 by ISA with the aim of facilitating participation of interested entities in the development process of the rules. The stakeholders who had replied to the survey included existing contractors, sponsoring States, environmentalists, academics, and nongovernmental organizations. Opinions given by them largely reflect their own interests. This paper aims to clarify the scope of the obligations regarding the environmental protection which may be imposed on contractors under the new regulations for the exploitation of manganese nodules. To do so, it first analyses the express provisions on environmental protection applicable to deep seabed mining included in the Law of the Sea Convention, its agreement on implementation of Part XI, and the regulations on exploration for manganese nodules. Secondly, it categorizes these obligations based on the categories of international obligations suggested by Combacau and Alland. Based on the categorizations this paper concludes that, in addition to the existing duties to protect deep seabed environment within the Law of the Sea Convention system, the following new obligations could be added: conservation of exploitation sites for a limited time after the contract is ceased; taking all necessary measures for rehabilitation of destroyed ecosystems that occurredas a result of mining activities; monitoring exploitation sites for a limited period time after the contract is ceased; observing rules and standards on safety of ships and environmental protection adopted under IMO instruments; regulation on the discharge of mine tailings from the facilities used for exploitation of deep sea minerals. Lastly, this paper attempts to provide ways of reflecting national interests in terms of potential obligations which may be included in the new regulations.

• 한국해양공학회지
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• 제24권1호
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• pp.47-52
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• 2010

This study presents a modified scheme for the radar image simulation of sea waves. A simulated radar image was obtained by taking into account the dot product of the directed vector from the radar and the normal vector of the sea surface. Moreover, to calculate the radar image, we used the radar received power and radar cross section. To demonstrate the effectiveness of the proposed scheme, the wave spectrum from field data was utilized to obtain the simulated sea waves. The radar image was simulated using numerically generated sea waves. The wave statistics from the simulation agrees comparatively with those of the original field data acquired by real radar measurements.