A Yellow Sea Monitoring Platform and Its Scientific Applications

Kim, Yong Sun; Jang, Chan Joo; Noh, Jae Hoon; Kim, Kyung‐Tae; Kwon, Jungkee; Min, Yongchim; Jeong, Jongmin; Lee, Jaeik; Min, In-Ki; Shim, Jae-Seol; Byun, Do-Seong; Kim, Jinkwon; Jeong, Jin-Yong

doi:10.3389/fmars.2019.00601

Cited by 20 publications

(12 citation statements)

References 17 publications

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“…S-ORS, the third ocean research station constructed by the Korea Institute of Ocean Science and Technology (KIOST) in 2014, lies in the central Yellow Sea approximately 50 km away from the western coast of the Korean Peninsula (37 • 25 23.28 N, 124 • 44 16.94 E). This station was constructed to keep track of the oceanic and atmospheric environments of the Yellow Sea (Ha et al, 2019;Kim et al, 2019). This monitoring platform is equipped with dozens of oceanic, meteorological, and environmental sensors.…”

Section: Observational Site and Socheongcho Ocean Research Station Datamentioning

confidence: 99%

Physical Processes in Sea Fog Formation and Characteristics of Turbulent Air-Sea Fluxes at Socheongcho Ocean Research Station in the Yellow Sea

Yun

2022

Front. Mar. Sci.

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The Yellow Sea is the most fog-prone region of the East Asian marginal seas. Since sea fog is caused due to complex interactions between atmospheric and oceanic environments, direct observations can help understand the physical processes involved in fogging over the oceans. Completed in 2014, the Socheongcho Ocean Research Station (S-ORS) plays a critical role in monitoring air-sea interactions over the Yellow Sea. This study aimed to evaluate the conditions favorable for fog generation and the physical processes underlying it using a suite of observations and turbulent heat flux data from S-ORS. First, we used the visibility data from S-ORS to quantify the frequency of sea fog over the Yellow Sea. From April to June 2016, sea-fog occurred 61 times, with a maximum duration of 135 h (approximately 5.6 days). Next, to understand the origin and characteristics of air mass associated with fog events, we classified the primary airflow paths in the region using a Hybrid Single-Particle Lagrangian Integrated Trajectory model. Among the four clusters identified from the cluster analysis, the third and fourth had distinct physical properties characteristic of cold and warm fog, respectively. The third cluster was characterized by relatively weak or negative heat advection and weak vertical mixing, while the fourth one featured strong positive heat transport and moisture convergence over the Yellow Sea. Finally, based on cluster analysis, we choose the representative cases related to these two clusters observed at S-ORS and compared the characteristics of turbulent air-sea fluxes associated with fog formations.

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Section: Observational Site and Socheongcho Ocean Research Station Datamentioning

confidence: 99%

Physical Processes in Sea Fog Formation and Characteristics of Turbulent Air-Sea Fluxes at Socheongcho Ocean Research Station in the Yellow Sea

Yun

2022

Front. Mar. Sci.

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“…During this period, biofouling on the salinity sensor is a key problem, significantly reducing sensor performance as shown in Figure 9. To minimize data drift in the salinity observations, three technical solutions were applied and studied, including the use of (1) copper taping (Venkatesan et al, 2017), (2) UV light beams (Corin et al, 1996), and (3) electrode type salinity sensors (Kim et al, 2019). The use of copper taping around the RBR sensor (Figure 3B) initially hindered biofouling, but the effect lasted only a couple of weeks (not shown) and did not produce measurable effects over observational timescales in the ORS experiments.…”

Section: Temperature and Salinity In The Water Columnmentioning

confidence: 99%

“…This influence is primarily via the transport of heat, salt, and other materials by the Tsushima Warm Current (originating from the northward branch of the Kuroshio Current, Nitani, 1972;Lie and Cho, 1994) and/or by the Taiwan Warm Current (Beardsley et al, 1985;Fang et al, 1991;Kim et al, 2005). This sea also influences the weather and climate of the Korean Peninsula, via heat transport and other ECS air-sea interactions (Kim et al, 2019). Moreover, the majority of typhoons approach the Korean Peninsula during summer and early autumn via the ECS (Moon et al, 2010;Kim et al, 2014;Byun et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Ocean and Atmospheric Observations at the Remote Ieodo Ocean Research Station in the Northern East China Sea

et al. 2021

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For open ocean environments, it is rare to find continuous, simultaneous air and sea observation records due to the challenges of instrument installation and maintenance. The Ieodo Ocean Research Station (Ieodo ORS), a remote ocean site located in the northern East China Sea with its harsh oceanic and atmospheric environment, provides a platform for the concurrent monitoring of air and sea environments. Since 2014, the Korea Hydrographic and Oceanographic Agency has run the “Ieodo ORS field trip program,” via which researchers are able to stay at the station for a week or more. This work reports technical lessons learned over 5 years from five Ieodo ORS research projects launched in 2016. Over the course of these projects, Ieodo ORS has monitored sea surface temperature, temperature and salinity in the water column, seawater pH, air pollutants, and solar radiation. The purpose of this paper is to facilitate the success of future research activities in similar environments by sharing our experiences and “best practices.”

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“…같은 대륙붕 해역에서 수행된 관측선 및 계류 관측의 경우 에는 정확도와 관측 자료의 처리 절차에서 다소 문제가 있 으며 (Oh et al, 2006;Kim et al 2020;Park et al 2020 (Ha et al, 2019;Kim et al 2019;Byun et al, 2021). 수온과 염분을 관측하기 위해 이어도 해양과학 기지는 표층(3m), 중층(20.5m), 저층(38m), 그리고 가거초와 소청초 해양과학기지는 표층(3m)에 Aanderaa사의 CT3919 전도도-수온(Conductivity-Temperature, CT) 센서를 설치하 여 운영하고 있다.…”

Section: 이재익⋅이수찬⋅정종민⋅민용침⋅정진용⋅김용선unclassified

“…수온의 경우에는 그 정확도와 오차, 품질관리 절차가 비 교적 정확하게 알려져 있어 (Min et al, 2020), 기후 변화에 따른 해양 환경 변동성 및 영향, 그리고 악기상 발생에 따른 해양 대기 상호작용 융합 연구 등에 대기 관측 자료와 더불 어 다각도로 활용되고 있다 (Kim et al 2019;Ha et al, 2019;Byun et al, 2021). 하지만, 염분 자료의 경우에는 수온에 비 하여 활용 연구가 극히 드물다.…”

Section: 이재익⋅이수찬⋅정종민⋅민용침⋅정진용⋅김용선unclassified

Salinity drift prevention experiments in the Korea ocean research stations and suggestions for high quality salinity observation

Lee¹,

Lee²,

Jeong³

et al. 2021

J Coast Disaster Prev

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The importance of salinity has been highlighted to cope with climate changes and disaster prevention. The salinity of accuracy up to 0.005 is normally required in an open ocean to understand various oceanic and climatic phenomena; however, the reliability of salinity measured on the coast and open seas around Korea was low due to the lack of a standardized observation system and post-processing of quality verification. Korea Ocean Research Stations (KORS) has been producing salinity time series since 2003 through the Aanderaa conductivity-temperature (CT) 3919 inductive sensors, which have an advantage of on-site maintenance but tend to drift toward a lower conductivity because of biological attachments to the sensor. This study applied copper taping and UV light exposure techniques to the sensors and then compared its salinity measurements with RBR CTD mooring observations and SeaBird19 CTD profiles to assess a biofouling effect on salinity observations. This experiment shows that the salinity from the CT sensor without biofouling prevention starts to drift in a week, particularly for a surface sensor. This biofouling induced the decrease of salinity up to 10 in a month. The copper taping methodology efficiently suppressed the biological attachment but disturbed an electromagnetic field around the sensor, thus resulting in unrealistic salinity values. When UV light was periodically exposed at a distance of about 5 cm away from the CT sensor, relatively stable salinity could be observed without significant drift at least in two months. Besides, the SBE37 CTD, an electrode-type sensor, seems to be relatively free from biofouling but has difficulties in sensor maintenance and a sensor calibration process. Our results underline a double installation of salinity observation equipment with UV light exposure. In addition, the pre-calibration of a CT(D) sensor and post-verification should be included in a standard procedure for high-quality salinity measurement.

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A Yellow Sea Monitoring Platform and Its Scientific Applications

Cited by 20 publications

References 17 publications

Physical Processes in Sea Fog Formation and Characteristics of Turbulent Air-Sea Fluxes at Socheongcho Ocean Research Station in the Yellow Sea

Physical Processes in Sea Fog Formation and Characteristics of Turbulent Air-Sea Fluxes at Socheongcho Ocean Research Station in the Yellow Sea

Ocean and Atmospheric Observations at the Remote Ieodo Ocean Research Station in the Northern East China Sea

Salinity drift prevention experiments in the Korea ocean research stations and suggestions for high quality salinity observation

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