Hindcast of the mesoscale eddy field in the Southeastern Baltic Sea: Model output vs satellite imagery

被引:6
|
作者
Zhurbas, Victor [1 ]
Vali, Germo [2 ]
Kostianoy, Andrey [1 ,3 ]
Lavrova, Olga [4 ]
机构
[1] RAS, Shirshov Inst Oceanol, 36 Nahimovskiy Prospekt, Moscow 117997, Russia
[2] Tallinn Univ Technol, Dept Marine Syst, Tallinn, Estonia
[3] SYu Witte Moscow Univ, Moscow, Russia
[4] RAS, Space Res Inst, Moscow, Russia
来源
RUSSIAN JOURNAL OF EARTH SCIENCES | 2019年 / 19卷 / 04期
基金
俄罗斯基础研究基金会;
关键词
Mesoscale eddy; Baltic Sea; numerical modeling; satellite imagery; TURBULENCE CLOSURE MODELS; OIL POLLUTION; VARIABILITY; DYNAMICS; SURFACE; PART;
D O I
10.2205/2019ES000672
中图分类号
P [天文学、地球科学];
学科分类号
07 ;
摘要
An ultra-high resolution circulation model (0.125 nautical mile grid) of the Southeastern Baltic Sea is compiled from the General Estuarine Transport Model (GETM) in order to simulate the mesoscale eddy field in the area. The model results are compared with optical and infrared satellite imagery available for the period of May-August 2015. Mesoscale eddies detected in the satellite images are reasonably well identified in the simulated patterns of the sea surface temperature, currents, and floating Lagrangian particles.
引用
收藏
页数:17
相关论文
共 50 条
  • [41] Mesoscale eddy activity in the southern Benguela upwelling system from satellite altimetry and model data
    Rubio, Anna
    Blanke, Bruno
    Speich, Sabrina
    Grima, Nicolas
    Roy, Claude
    PROGRESS IN OCEANOGRAPHY, 2009, 83 (1-4) : 288 - 295
  • [42] A Markov random field model for classification of multisource satellite imagery
    Solberg, AHS
    Taxt, T
    Jain, AK
    IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING, 1996, 34 (01): : 100 - 113
  • [43] Automated tracking of dry intrusions on satellite water vapour imagery and model output
    Michel, Y.
    Bouttier, F.
    QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY, 2006, 132 (620) : 2257 - 2276
  • [44] Characteristics of sea surface circulation and eddy field in the South China Sea revealed by satellite altimetric data
    Morimoto A.
    Yoshimoto K.
    Yanagi T.
    Journal of Oceanography, 2000, 56 (3) : 331 - 344
  • [45] The Mediterranean Sea overturning circulation: A hindcast simulation (1958-2015) with an eddy-resolving (1/36°) model
    Mavropoulou, Apostolia-Maria
    Vervatis, Vassilios
    Sofianos, Sarantis
    DEEP-SEA RESEARCH PART I-OCEANOGRAPHIC RESEARCH PAPERS, 2022, 187
  • [46] A Deep Learning Model for Oceanic Mesoscale Eddy Detection Based on Multi-source Remote Sensing Imagery
    Liu, Yingjie
    Li, Xiaofeng
    Ren, Yibin
    IGARSS 2020 - 2020 IEEE INTERNATIONAL GEOSCIENCE AND REMOTE SENSING SYMPOSIUM, 2020, : 6762 - 6765
  • [47] Rotation of floating particles in submesoscale cyclonic and anticyclonic eddies: a model study for the southeastern Baltic Sea
    Zhurbas, Victor
    Vali, Germo
    Kuzmina, Natalia
    OCEAN SCIENCE, 2019, 15 (06) : 1691 - 1705
  • [48] Monitoring and Tracking the Green Tide in the Yellow Sea With Satellite Imagery and Trajectory Model
    Xu, Qing
    Zhang, Hongyuan
    Cheng, Yongcun
    Zhang, Shuangshang
    Zhang, Wei
    IEEE JOURNAL OF SELECTED TOPICS IN APPLIED EARTH OBSERVATIONS AND REMOTE SENSING, 2016, 9 (11) : 5172 - 5181
  • [49] Morphological changes in the Aral Sea: Satellite imagery and water balance model.
    Ressl, R
    Micklin, P
    DYING AND DEAD SEAS: CLIMATIC VERSUS ANTHROPIC CAUSES, 2004, 36 : 77 - 89
  • [50] Spring thermocline formation in the coastal zone of the southeastern Baltic Sea based on field data in 2010–2013
    I. P. Chubarenko
    N. Yu. Demchenko
    E. E. Esiukova
    O. I. Lobchuk
    K. V. Karmanov
    V. A. Pilipchuk
    I. A. Isachenko
    A. F. Kuleshov
    V. Ya. Chugaevich
    N. B. Stepanova
    V. A. Krechik
    A. V. Bagaev
    Oceanology, 2017, 57 : 632 - 638
12345