青岛近海大型水母漂移集合预测方法研究

作者：吴玲娟  高松  刘桂艳  白涛

单位：山东省海洋生态环境与防灾减灾重点实验室, 国家海洋局北海预报中心, 山东青岛266033

关键词：水母灾害 集合预报 水母垂直运动 漂移预测

分类号：Q958.8

出版年·卷·期（页码）：2015·32·第二期（62-71）

摘要：

考虑水母垂直运动等自主运动,基于集合预报和拉格朗日粒子追踪方法,建立青岛近海大型水母的集合漂移预测模型。并利用2012-2013 年青岛近海水母实时监测数据和集合漂移预测模型,快速预测水母集合漂移轨迹、速度、趋势和可能影响范围等要素。通过分析水母监测数据和数值模拟结果,在水母如何自主运动及其机理尚不十分清楚的情况下,多轨迹漂移预测结果比单轨迹的更合理、科学、可信,能够传达更多的信息量,对水母灾害的应急处置更具有指导意义。

In this paper, by considering the vertical movement of large jellyfish, the ensemble drift model of jellyfish in the coastal waters of Qingdao is developed based on ensemble forecast and lagrange particle tracking method. By using observation during 2012-2013, ensemble drift forecast model is carried out to predict ensemble drift trajectory, velocity, trend, and affected scope of jellyfish. Through analysis of observation and numerical simulation results, the results show that ensemble forecast of drift trajectory is more reasonable, scientific, reliable than single forecast, and able to provide more information to deal with jellyfish disaster.

参考文献：

[1] Brodeur R D, Mills C E, Overland J E, et al. Evidence for a substantial increase in gelatinous zooplankton in the Bering Sea, with possible links to climate change[J]. Fisheries Oceanography, 1999, 8(4): 296-306. [2] Mills C E. Jellyfish blooms: are populations increasing globally in response to changing ocean conditions? [J]. Hydrobiologia, 2001, 451(1-3): 55-68. [3] Nagai T. Recovery of fish stocks in the Seto Inland Sea[J]. Marine Pollution Bulletin, 2003, 47(1-6): 126-131. [4] Greve W. The 1989 German Bight Invasion of Muggiaea atlantica[J]. ICES Journal Marine Science, 1994, 5l(4): 355-358. [5] 程家骅, 李圣法, 丁峰元, 等. 东、黄海大型水母暴发现象及其可 能成因浅析[J]. 现代渔业信息, 2004, 19(5): 10-12. [6] 王世伟, 张光涛, 孙松, 等. 2011 年夏季胶州湾三种大型水母的种 群动态研究[J]. 海洋与湖沼, 2012, 43(3): 471-479. [7] 孙松. 对黄、东海水母暴发机理的新认知[J], 海洋与湖沼, 2012, 43(3): 406-410. [8] 张海彦, 赵亮, 魏皓. 青岛外海夏季水母路径溯源研究[J], 海洋与 湖沼, 2012, 43(3): 662-668. [9] Barz K, Hinrichsen H -H, Hirche H -J. Scyphozoa in the Bornholm basin, (central Baltic Sea)-The role of advection[J]. Journal Marine Systems, 2006, 60(1-2): 167-176. [10] Moon J -H, Pang I -C, Yang J -Y, et al. Behavior of the giant jellyfish Nemopilema nomurai in the East China Sea and East/ Japan Sea during the summer of 2005: A numerical model approach using a particle-tracking experiment [J]. Journal of Marine Systems, 2010, 80(1-2): 101-114. [11] 罗晓凡, 魏皓, 王玉衡. 黄、东海水母质点追踪影响因素分析[J], 海洋与湖沼, 2012, 43(3): 635-642. [12] Johnson D R, Perry H M, Burke W D. Developing jellyfish strategy hypotheses using circulation models [J]. Hydrobiologia, 2001, 451(1-3): 213-221. [13] Johnson D R, Perry H M, Graham W M. Using nowcast model currents to explore transport of non-indigenous jellyfish into the Gulf of Mexico[J]. Marine Ecology Progress Series, 2005, 305: 139-146. [14] Berline L, Zakardjian B, Molcard A, et al. Modeling jellyfish Pelagia noctiluca transport and stranding in the Ligurian Sea[J]. Marine Pollution Bulletin , 2013, 70(1-2): 90-99. [15] Graham W M, Pagès F, Hamner W M. A physical context for gelatinous zooplankton aggregations: a review[J]. Hydrobiologia, 2001, 451(1-3): 199-212. [16] 张芳. 黄东海胶质浮游动物水母类研究[D]. 青岛: 中国科学院 海洋研究所, 2008: 1-130. [17] Barz K, Hirche H-J. Abundance, distribution and prey composition of scyphomedusae in the southern North Sea[J]. Marine Biology, 2007, 151(3): 1021-1033. [18] Naoto H , Toshihiro W, Yoshiki M, 2009. Swimming depths of the giant jellyfish Nemopilema nomurai investigated using pop-up archival transmitting tags and ultrasonic pingers[J]. Fisheries Science, 75(4): 947-956. [19] Pagès F, White M G, Rodhouse P G. Abundance of gelatinous carnivores in the nekton community of the Antarctic Polar Frontal Zone in summer 1994 [J]. Marine Ecology Progress Series, 1996, 141: 139-147. [20] Schuyler Q, Sullivan B K. Light responses and die1 migration of the scyphomedusa Chrysaora quinquecirrha in mesocosms[J]. Journal Plankton Research, 1997, 19(10): 1417-1428. [21] Eiane K, Aksnes D L, Bagøien E, et al. Fish or jellies-a question of visibility?[J]. Limnology and Oceanography, 1999, 44(5): 1352-1357. [22] Ezer T, Arango H G, Shchepetkin A F. Developments in terrainfollowing ocean models: intercomparisons of numerical aspects[J]. Ocean Modelling, 2002, 4(3-4): 249-267. [23] Shchepetkin A F, McWilliams J C. The regional oceanic modeling system (ROMS):a split-explicit, free-surface, topographyfollowing- coordinate oceanic model[J]. Ocean Modelling, 2005, 9 (4): 347-404. [24] Fennel K, Wilkin J, Levin J, et al. Nitrogen cycling in the Middle Atlantic Bight: results from a three-dimensional model and implications for the North Atlantic nitrogen budget[J]. Global Biogeochemical Cycles, 2006, 20(3): GB3007, doi: 3010.1029/ 2005GB002456. [25] Penven P, Lutjeharms J R E, Marchesiello P, et al. Generation of cyclonic eddies by the Agulhas Current in the lee of the Agulhas Bank[J]. Geophysical Research Letters, 28(6): 1055-1058. [26] Epstein E S. Stochastic dynamic prediction[J]. Tellus, 1969, 21 (6): 739-759. [27] Leith C E. Theoretical skill of monte carlo forecasts[J]. Monthly Weather Review. 1974, 102(6): 409-418. [28] Toth Z, Kalnay E. Ensemble forecasting at NCEP and the breeding method[J]. Monthly Weather Review, 1997, 125(12): 3297-3319. [29] Zhu Y J, Toth Z, Wobus R, et al. The economic value of ensemble-based weather forecasts[J]. Bulletin of the American Meteorolgical Society, 2002, 83(1): 73-83. [30] Joslyn S, Pak K, Jones D, et al. The effect of probabilistic information on threshold forecasts[J]. Weather and Forecasting, 2007, 22(4): 804-812. [31] Nadav-Greenberg L, Joslyn S L. Uncertainty forecasts improve decision making among nonexperts [J]. Journal of Cognitive Engineering and Decision Making, 2009, 3: 209-227. [32] 付翔, 董剑希, 马经广, 等. 0814 号强台风“黑格比”风暴潮分析 与数值模拟[J]. 海洋预报, 2009, 26(4): 68-75. [33] 高松, 黄娟, 白涛, 等, 无主漂油源集合预测方法研究[J]. 海洋科 学, 2014, 38(3): 42-45.

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