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EM120(multi-beam echo sounder)을 이용한 지형조사 시 적용되는 해수 중 음속 측정의 중요성; 수중음속 측정장비의 특성 비교
함동진,김현섭,이근창,Ham, Dong-Jin,Kim, Hyun-Sub,Lee, Gun-Chang 한국해양학회 2008 바다 Vol.13 No.3
다중음향측심기에 의한 해저 지형조사는 해양 연구에 기본적인 자료를 제공한다. 지형조사를 위해 수층의 음속을 측정하는데 정확한 수심별 음속 측정은 지형조사 결과에 큰 영향을 미친다. 광역 지형조사 시 공간의 이동에 따라 수층별로 음속의 변화를 일으키는 요인이 발생할 수 있고, 측정 기기별(Sound Velocity Profiler, Conductivity-Temperature-Depth, eXpendable BathyThermograph) 특성에 의해 음속을 달리 측정할 가능성이 있다. 이 연구에서는 음속수직분포도(sound velocity profile)가 달라짐에 따라 발생하는 해저 지형의 변화를 MB-System을 이용하여 비교하였다. 분석 결과 표층의 음속 변화에 비해 수온약층의 음속변화가 획득지형자료에 더 큰 영향을 미치는 것으로 나타났다. 각 기기별로 측정된 음속의 차이는 크지 않았고 해저 지형 결과에 큰 영향을 주지 않은 것으로 나타났다. 해저 지형조사를 위해 위 음속측정기기 중 어떠한 것을 사용하여도 무방하나 해저 지형조사 측선은 수층의 온도변화가 작은 방향으로 선정하는 것이 더 바람직하다. Bathymetric data collected using a multi-beam echo sounder during marine scientific survey is essential for geologic and oceanographic research works. Accurate measurment of sound velocity profile(SVP) in water-column is important for bathymetric data processing. SVP can vary at different locations during the survey undertaken for wide areas. In addition, an observational error can occur when different equipments(Sound Velocity Profiler, Conductivity Temperature Depth, eXpendable BathyThermograph) are used for measuring SVP at the same water column. In this study, we used an MB-system software to show changes in bathymetry caused by variation of SVP. The analyses showed that the sound velocity(SV) changes due to the depth and thickness of thermocline had more significant effects on the resulting bathymetric data than those of surface mixed layer. The observational errors between SVP measuring instruments did not cause much differneces in the processed bathymetric data. Bathymetric survey line is better to be established to the direction that the change of temperature can be minimize to reduce the variation of SVP during the data acquisition along the survey line.
북동태평양 KODOS 해역 심해 해저특성에 따른 초대형저서동물 분포
유옥환,손주원,함동진,이근창,김경홍 한국해양과학기술원 2014 Ocean and Polar Research Vol.36 No.4
In August, 2013, we collected epifaunal megabenthos using a deep sea camera (DSC) around a benthic impact study (BIS) site. This was located in the KR5 block of the Korea Deep Ocean Study (KODOS) area in the Northeastern Pacific. The DSC was positioned at 6.8 ± 2.9 m (SD) from the sea bottom and was operated from a position at 131o56.85' - 131o55.02'W for 2.3 h at a speed of 1-2 knot. The geographical features of the study area consisted of two structures; a trough in the middle and hills at the east and west sides. Sediment conditions were consistent within six blocks and were affected by slope and polymetallic nodule deposits. We analyzed 226 megafaunal species. Sipunculida comprised the highest percentage of individuals (39%), and the dominant epifaunal megabenthos were Hormathiidae sp., Primnoidae sp., Hexactinellida sp., Hyphalaster inermis, Freyella benthophila, Paelopatides confundens, Psychropotes longicauda, and Peniagone leander. More than 80% of the total density of megafauna occurred on sea plain (D- and E-blocks). We found two distinct groups in the community, one located on sea plains and the other along both sides of the sea slop. Our results suggest that geographical features such as slope and polymetalic nodule deposits are important in controlling the distribution of the epifaunal megabenthos around the KODOS area.
열수 플룸 검출을 위한 CTD Cast와 CTD Tow-yo 방법 비교
손주원,주종민,함동진,양승진,김종욱 한국해양과학기술원 2014 Ocean and Polar Research Vol.36 No.2
Directly searching for undiscovered hydrothermal vent sites is inefficient due to the practical difficulty of comprehensively imaging vent fields. Thus, most searches for hydrothermal vent sites rely on the detection of hydrothermal plumes from water column observation. Detecting and measuring the hydrothermal plumes are the most efficient way to infer the presence and distribution of hydrothermal vents. Both the array of vertical casting and lateral towing are the most common methods to discover hydrothermal plumes. In this study, we compared results of cast and tow-yo operations along the same section of a spreading center with a distance of 20.5 km in the North Fiji Basin for mapping hydrothermal plumes. Operation of CTD tow-yo provides a detailed pattern of plumes which enable us to locate the hydrothermal vents. On the other hand, identification of hydrothermal activity can be determined effectively by CTD cast with additional analysis of geochemical tracers. Reduction in the operating time is another advantage of CTD cast operation, especially for regional-scale survey. Our results show that the combination of CTD cast and tow-yo would improve the efficiency of the hydrothermal plume survey to locate new hydrothermal vent sites.