Statistical Characteristics of East Sea Mesoscale Eddies Detected,  Tracked,  and Grouped Using Satellite Altimeter Data from 1993 to 2017

KYUNGJAE Lee; SUNGHYUN Nam; YOUNG-GYU Kim

doi:10.7850/jkso.2019.24.2.267

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Article (Special Issue)

Statistical Characteristics of East Sea Mesoscale Eddies Detected, Tracked, and Grouped Using Satellite Altimeter Data from 1993 to 2017 인공위성 고도계 자료(1993-2017년)를 이용하여 탐지‧추적‧분류한 동해 중규모 소용돌이의 통계적 특성

31 May 2019. pp. 267-281

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Abstract

활발한 중규모 변동성으로 인해 해양 환경과 순환의 극심한 변화를 초래하는 동해 전역에서 장기간(1993-2017년) 수집된 인공위성 고도계 자료와 2015-2017년 기간의 4차례 승선 조사로 수집된 현장 관측 자료를 분석하여 중규모 소용돌이의 통계적 특성을 규명하였다. 동해 전역에서 해당 기간 동안 총 1,008개의 중규모 소용돌이를 탐지·추적·정의하고, 이를 27개의 그룹으로 분류하여, 전체 평균 및 각 그룹별 평균 지속기간(L, 일), 진폭(H, m), 반경(R, km), 단위 면적당 강도(EI, cm²/s²/km²), 타원율(e), 운동에너지(EKE, TJ), 가용위치에너지(APE, TJ) 및 전파 방향을 산출하였다. 인공위성 고도계 자료로부터 산출된 소용돌이의 중심, 경계, H 각각을 현장 관측 자료로부터 산출된 해당 수치와 비교하여 각각에 대한 불확실성을 중심 오차 2-10 km, 경계 오차 10-20 km, 진폭 오차 0.6-5.9 cm로 추정하였다. 정의된 모든 소용돌이들의 전기간 평균 L, H, R, EI, e, EKE, APE는 각각 95±104일, 3.5±1.5 cm, 39±6 km, 0.023±0.017 cm²/s²/km², 0.72±0.07, 23±21 TJ, 588±250 TJ로서 대양에 비해 전반적으로 L이 짧고, H, R은 작으며, EI는 강하고, EKE는 낮게, APE는 높게 나타났다. 또, 대양에서와 같은 뚜렷한 서향 전파 특성을 보이지 않고, 대체로 해류를 따라 이동하는 특성을 보였다. 아극전선(subpolar front)을 기준으로 남부 소용돌이 그룹의 L, H, R, EI, EKE, APE가 북부 그룹에 비해 더 길고, 크고, 강하며, 높고, 평균 해류 방향으로 더 멀리 이동하는 특성을 보였다. 뿐만 아니라 특정 방향으로의 이동이 뚜렷하지 않은 4개 그룹들(Wonsan Warm Eddy, Wonsan Cold Eddy, Western Japan Basin Warm Eddy, Northern Subpolar Frontal Cold Eddy groups)과 상대적으로 크고, 강하며, 높은 H, EI, EKE, APE에도 불구하고 오래 지속되지 않는(짧은 L) 특성을 보이는 3개 그룹들(Yamato Coastal Warm Eddy, Central Yamato Warm Eddy, Eastern Japan Basin Coastal Warm Eddy groups)도 제시하였다. 인공위성 고도계만으로는 잘 탐지되기 어려운 작은 규모의 소용돌이가 존재하는 동해 북부 해역에서는 소용돌이 그룹이 정의되지 않았으며, 본 연구에서 제시된 동해 평균 소용돌이 특성치의 과대추정 가능성이 토의되었다. 본 연구를 통해 1) 기존에 비교적 잘 알려진 울릉 난수성 소용돌이(Ulleung Warm Eddy)와 독 냉수성 소용돌이(Dok Cold Eddy) 그룹 외에도 Hokkaido Warm Eddy, Yamato Rise Warm Eddy와 같은 그룹들을 새로 정의하였고, 2) 대양의 중규모 소용돌이에 비해 전반적으로 그 L이 짧고, H, R은 작고, EKE는 낮으나, EI는 강하고, APE는 높으며, 서향 전파가 뚜렷하지 않은 동해의 중규모 소용돌이 특성을 규명했으며, 3) 동해 내에 그룹별로 상이한 중규모 소용돌이 그룹의 특성을 제시하였다.

Energetic mesoscale eddies in the East Sea (ES) associated with strong mesoscale variability impacting circulation and environments were statistically characterized by analyzing satellite altimeter data collected during 1993-2017 and in-situ data obtained from four cruises conducted between 2015 and 2017. A total of 1,008 mesoscale eddies were detected, tracked, and identified and then classified into 27 groups characterized by mean lifetime (L, day), amplitude (H, m), radius (R, km), intensity per unit area (EI, cm²/s²/km²), ellipticity (e), eddy kinetic energy (EKE, TJ), available potential energy (APE, TJ), and direction of movement. The center, boundary, and amplitude of mesoscale eddies identified from satellite altimeter data were compared to those from the in-situ observational data for the four cases, yielding uncertainties in the center position of 2-10 km, boundary position of 10-20 km, and amplitude of 0.6-5.9 cm. The mean L, H, R, EI, e, EKE, and APE of the ES mesoscale eddies during the total period are 95±104 days, 3.5±1.5 cm, 39±6 km, 0.023±0.017 cm²/s²/km², 0.72±0.07, 23±21 TJ, and 588±250 TJ, respectively. The ES mesoscale eddies tend to move following the mean surface current rather than propagating westward. The southern groups (south of the subpolar front) have a longer L, larger H, R, and higher EKE, APE; and stronger EI than those of the northern groups and tend to move a longer distance following surface currents. There are exceptions to the average characteristics, such as the quasi-stationary groups (the Wonsan Warm, Wonsan Cold, Western Japan Basin Warm, and Northern Subpolar Frontal Cold Eddy groups) and short-lived groups with a relatively larger H, higher EKE, and APE and stronger EI (the Yamato Coastal Warm, Central Yamato Warm, and Eastern Japan Basin Coastal Warm eddy groups). Small eddies in the northern ES hardly resolved using the satellite altimetry data only, were not identified here and discussed with potential over-estimations of the mean L, H, R, EI, EKE, and APE. This study suggests that the ES mesoscale eddies 1) include newly identified groups such as the Hokkaido and the Yamato Rise Warm Eddies in addition to relatively well-known groups (e.g., the Ulleung Warm and the Dok Cold Eddies); 2) have a shorter L; smaller H, R, and lower EKE; and stronger EI and higher APE than those of the global ocean, and move following surface currents rather than propagating westward; and 3) show large spatial inhomogeneity among groups.

Keywords

East Sea

Mesoscale eddies

Satellite altimetry

Eddy characteristics

Eddy movement

EKE

APE

References

김봉채, 최복경, 김병남, 2012. 동해에서 저주파 음파전파에 미치는 난수성 소용돌이의 영향. Ocean. Polar Res., 34(3): 325-335.

10.4217/OPR.2012.34.3.325

박경애, 박지은, 최병주, 변도성, 이은일, 2013. 해양관측을 통해 획득한 과학적 지식에 기반한 과학교과서 동해 해류도. 한국해양학회지 바다, 18(4): 234-265.

10.7850/jkso.2013.18.4.234

Böning, C.W. and R.G. Budich, 1992. Eddy dynamics in a primitive equation model: Sensitivity to horizontal resolution and friction. J. Phys. Oceanogr., 22(4): 361-381.

10.1175/1520-0485(1992)022<0361:EDIAPE>2.0.CO;2

Byun, S.S., J.J. Park, K.I. Chang and R.W. Schmitt, 2010. Observation of near‐inertial wave reflections within the thermostad layer of an anticyclonic mesoscale eddy. Geophys. Res. Lett., 37(1): L01606.

10.1029/2009GL041601

Chaigneau, A., A. Gizolme and C. Grados, 2008. Mesoscale eddies off Peru in altimeter records: Identification algorithms and eddy spatio-temporal patterns. Prog. Oceanogr., 79(2-4): 106-119.

10.1016/j.pocean.2008.10.013

Chang, K.I., C.I. Zhang, C. Park, D.J. Kang, S.J. Ju and S.H. Lee, 2016. Oceanography of the East Sea (Japan Sea). Edited by Wimbush, M., Springer, 460.

10.1007/978-3-319-22720-7

Chelton, D.B., M.G. Schlax and R.M. Samelson, 2011. Global observations of nonlinear mesoscale eddies. Prog. Oceanogr., 91(2): 167-216.

10.1016/j.pocean.2011.01.002

Chen, G., D. Wang and Y. Hou, 2012. The features and interannual variability mechanism of mesoscale eddies in the Bay of Bengal. Cont. Shelf Res., 47: 178-185.

10.1016/j.csr.2012.07.011

Chen, G., Y. Hou and X. Chu, 2011. Mesoscale eddies in the South China Sea: Mean properties, spatiotemporal variability, and impact on thermohaline structure. J. Geophys. Res., 116(C6): C06018.

10.1029/2010JC006716

Eden, C., 2007. Eddy length scales in the North Atlantic Ocean. J. Geophys. Res., 112(C6): C06004.

10.1029/2006JC003901

Faghmous, J.H., I. Frenger, Y. Yao, R. Warmka, A. Lindell and V. Kumar, 2015. A daily global mesoscale ocean eddy dataset from satellite altimetry. Sci. Data, 2: 150028.

10.1038/sdata.2015.2826097744PMC4460914

Hong, G.H., D.K. Lee, D.B. Yang, Y.I. Kim, J.H. Park and C.H. Park, 2013. Eddy-and wind-sustained moderate primary productivity in the temperate East Sea (Sea of Japan). Biogeosciences, 10(6): 10429-10458.

10.5194/bgd-10-10429-2013

Ichiye, T. and K. Takano, 1988. Mesoscale eddies in the Japan Sea. La mer, 26(2): 69-75.

Isoda, Y., 1994. Warm eddy movements in the eastern Japan Sea. J. Oceanogr. Soc. Japan, 50(1): 1-15.

10.1007/BF02233852

Isoda, Y., 1996. Interaction of a warm eddy with the coastal current at the eastern boundary area in the Tsushima Current region. Cont. Shelf Res., 16(9): 1149-1163.

10.1016/0278-4343(95)00057-7

Kang, D. and E.N. Curchitser, 2015. Energetics of eddy-mean flow interactions in the Gulf Stream region. J. Phys. Oceanogr., 45(4): 1103-1120.

10.1175/JPO-D-14-0200.1

Kang, D. and O. Fringer, 2010. On the calculation of available potential energy in internal wave fields. J. Phys. Oceanogr., 40(11): 2539-2545.

10.1175/2010JPO4497.1

Kim, K., K.R. Kim, Y.G. Kim, Y.K. Cho, D.J. Kang, M. Takematsu and Y. Volkov, 2004. Water masses and decadal variability in the East Sea (Sea of Japan). Prog. Oceanogr., 61(2-4): 157-174.

10.1016/j.pocean.2004.06.003

Kim, Y.G., K. Kim, Y.K. Cho and H. Ossi, 2000. CTD data processing for CREAMS expeditions: Thermal-lag correction of Sea-Bird CTD. Ocean Sci. J., 35(4): 192-199.

Lee, D.K. and P.P. Niiler, 2005. The energetic surface circulation patterns of the Japan/East Sea. Deep-sea Res. II, 52(11-13): 1547-1563.

10.1016/j.dsr2.2003.08.008

Lee, D.K. and P.P. Niiler, 2010. Eddies in the southwestern East/Japan Sea. Deep-sea Res. I, 57(10): 1233-1242.

10.1016/j.dsr.2010.06.002

Lim, J.H., S. Son, J.W. Park, J.H. Kwak, C.K. Kang, Y.B. Son and S.H. Lee, 2012. Enhanced biological activity by an anticyclonic warm eddy during early spring in the East Sea (Japan Sea) detected by the geostationary ocean color satellite. Ocean Sci. J., 47(3): 377-385.

10.1007/s12601-012-0035-1

Lorenz, E.N., 1955. Available potential energy and the maintenance of the general circulation. Tellus, 7(2): 157-167.

10.3402/tellusa.v7i2.8796

Mitchell, D.A., W.J. Teague, M. Wimbush, D.R. Watts and G.G. Sutyrin, 2005. The Dok cold eddy. J. Phys. Oceangr., 35(3): 273-288.

10.1175/JPO-2684.1

Morimoto, A., T. Yanagi and A. Kaneko, 2000. Eddy field in the Japan Sea derived from satellite altimetric data. J. Oceanogr. Soc. Japan, 56(4): 449-462.

10.1023/A:1011184523983

Morison, J., R. Andersen, N. Larson, E. D’Asaro and T. Boyd, 1994. The correction for thermal-lag effects in Sea-Bird CTD data. J. Atmos. Ocean. Tech., 11(4): 1151-1164.

10.1175/1520-0426(1994)011<1151:TCFTLE>2.0.CO;2

Nam, S. and J.H. Park, 2008. Semidiurnal internal tides off the east coast of Korea inferred from synthetic aperture radar images. Geophys. Res. Lett., 35(5): L05602.

10.1029/2007GL032536

Nam, S., S.T. Yoon, J.H. Park, Y.H. Kim and K.I. Chang, 2016. Distinct characteristics of the intermediate water observed off the east coast of Korea during two contrasting years J. Geophys. Res., 121(7): 5050-5068.

10.1002/2015JC011593

Nan, F., Z. He, H. Zhou and D. Wang, 2011. Three long‐lived anticyclonic eddies in the northern South China Sea. J. Geophys. Res., 116(C5): C05002.

10.1029/2010JC006790

Park, J.H. and D.R. Watts, 2005. Near‐inertial oscillations interacting with mesoscale circulation in the southwestern Japan/East Sea. Geophys. Res. Lett., 32(10): L10611.

10.1029/2005GL022936

Park, J.H. and D.R. Watts, 2006. Internal tides in the southwestern Japan/East Sea, J. Phys. Oceanogr., 36: 22-34.

10.1175/JPO2846.1

Prants, S.V., V.I. Ponomarev, M.V. Budyansky, M.Y. Uleysky and P.A. Fayman, 2015. Lagrangian analysis of the vertical structure of eddies simulated in the Japan Basin of the Japan/East Sea. Ocean Model., 86: 128-140.

10.1016/j.ocemod.2014.12.010

Rhines, P.B., 1975. Waves and turbulence on a beta-plane. J. Fluid Mech., 69(3): 417-443.

10.1017/S0022112075001504

Shin, H.R., C.W. Shin, C. Kim, S.K. Byun and S.C. Hwang, 2005. Movement and structural variation of warm eddy WE92 for three years in the western East/Japan Sea. Deep-sea Res. II, 52(11-13): 1742-1762.

10.1016/j.dsr2.2004.10.004

Souza, J.M.A.C., C. de Boyer Montégut and P.Y. Le Traon, 2011. Comparison between three implementations of automatic identification algorithms for the quantification and characterization of mesoscale eddies in the South Atlantic Ocean. Ocean Sci., 7(3): 317-334.

10.5194/os-7-317-2011

Takematsu, M., A.G. Ostrovski and Z. Nagano, 1999. Observations of eddies in the Japan Basin interior. J. Oceanogr. Soc. Japan, 55(2): 237-246.

10.1023/A:1007846114165

Toba, Y., H. Kawamura, F. Yamashita and K. Hanawa, 1984. Structure of horizontal turbulence in the Japan Sea. In Ocean Hydrodynamics of the Japan and East China Seas, Elsevier, 39: 317-332.

10.1016/S0422-9894(08)70309-X

Zu, T., D. Wang, C. Yan, I. Belkin, W. Zhuang and J. Chen, 2013. Evolution of an anticyclonic eddy southwest of Taiwan. Ocean Dyn., 63(5): 519-531.

10.1007/s10236-013-0612-6

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 :2
Pages :267-281
Received Date : 2019-02-28
Revised Date : 2019-04-14
Accepted Date : 2019-04-28
DOI :https://doi.org/10.7850/jkso.2019.24.2.267

The Sea Journal of the Korean Society of OceanographyISSN:1226-2978(Print) 2671-8820(Online)한국해양학회

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