收稿日期: 2011-06-28
修回日期: 2011-09-01
网络出版日期: 2011-11-10
基金资助
国家重点基础研究发展计划项目“北太平洋副热带环流变异及其对我国近海动力环境的影响”(编号:2007CB411800)资助.
Advances in the Study of North Pacific Gyre Oscillation
Received date: 2011-06-28
Revised date: 2011-09-01
Online published: 2011-11-10
从观测事实和动力机制两方面,对近年发现的新的气候模态——北太平洋涡旋振荡(NPGO) 的研究成果进行系统总结。NPGO的空间结构表现为北太平洋上海表高度异常(SSHA) 的正负中心呈南北偶极子分布,当NPGO位于正位相时,南北涡流都加强,这种加强是由风应力旋度及风生涌流所驱动的。关于NPGO的机制研究发现,NPGO是中纬太平洋大气在海洋的表现,且热带与中纬度之间的大气、海洋耦合动力机制对NPGO波动的产生也有影响。并初步提出今后研究的重点:北太平洋气候模态空间结构的改变问题;大气与NPGO之间相互作用的机理;NPGO在生态迁移中所起的作用;NPGO对我国天气气候低频变异的影响。
张立凤, 吕庆平, 张永垂 . 北太平洋涡旋振荡研究进展[J]. 地球科学进展, 2011 , 26(11) : 1143 -1149 . DOI: 10.11867/j.issn.1001-8166.2011.11.1143
The studies of the new climate mode-North Pacific Gyre Oscillation (NPGO) were reviewed, focusing on the observation phenomenon and dynamic mechanisms. The spatial structure of NPGO mode was characterized by a dipole-like center of the sea surface height anomalies in the North Pacific.The NPGO represented an intensification of both the subpolar and subtropical gyres when in positive phase, and this intensification was driven by openocean wind stress curl anomalies and by variations in wind-driven coastal upwelling. The NPGO was the oceanic express of the mid-latitude atmospheric NPO. The tropical coupled dynamics were involved in forcing the NPGO fluctuations, suggesting that the coupling effect of atmosphere and ocean between tropical Pacific and mid-latitude Pacific was important to illustrate the dynamic mechanisms of NPGO. Meanwhile, future prospects were advanced as follows: the variations of spatial structure of climate modes in the North Pacific; the relationship and interaction between atmospheric mode and NPGO mode; the roles of NPGO in the ecological transition; the influence of NPGO to interdecadal climate variabilities in China.
Key words: North Pacific; Gyre oscillation; Climate modes; Interdecadal variability
[1]Mantua N J, Hare S R, Zhang Y, et al. A Pacific interdecadal climate oscillation with impacts on salmon production[J].Bulletin of the American Meteorological Society,1997, 78(6):1 069-1 079.
[2]Zhang Y, Norris J R, Wallace J M. Seasonality of large scale atmosphere ocean interaction over the North Pacific[J].Journal of Climate,1998,11(10): 2 473-2 481.
[3]Yang Xiuqun, Zhu Yimin, Xie Qian, et al. Advances in studies of Pacific decadal oscillation[J]. Chinese Journal of Atmosphere Science,2004, 28(6) : 979-992.[杨修群,朱益民,谢倩,等.太平洋年代际振荡的研究进展[J].大气科学, 2004, 28 (6) :979-992.]
[4]Wang Hui, Wang Dongxiao, Du Yan.Overseas advances in physical oceanography studies in 2002[J].Advances in Earth Science, 2003, 18(5) :797-805.[王辉, 王东晓, 杜岩.2002年国内外物理海洋学研究主要进展[J].地球科学进展, 2003, 18(5) :797-805.]
[5]Lynn R J, Baumgartner T, Garcia J, et al. The state of the California Current, 1997-1998:Transition to El Niño conditions[J].California Cooperative Oceanic Fisheries Investigations Reports,1998, 39:25-49.
[6]Di Lorenzo E, Schneider N, Cobb K M, et al. North Pacific Gyre Oscillation links ocean climate and ecosystem change[J].Geophysical Research Letters,2008, 35: L08607,doi: 10.1029/2007GL032838.
[7]Meehl G A, Goddard L, Murphy J, et al. Decadal prediction: Can it be skillful?[J].Bulletin of the American Meteorological Society,2009, 90(10):1 467-1 485.
[8]Murphy J, Kattsov V, Keenlyside N, et al. Towards prediction of decadal climate variability and change[J].Procedia Environmental Sciences, 2010,1:287-304.
[9]Solomon A, Goddard L, Kumar A, et al. Distinguishing the roles of natural and anthropogenically forced decadal climate variability: Implication for prediction[J]. Bulletin of the American Meteorological Society,2011,92(2):141-156.
[10]Bond N A, Overland J E, Spillane M, et al. Recent shifts in the state of the North Pacific[J]. Geophysical Research Letters, 2003, 30(23):2 183.
[11]Doney S C, Yeager S, Danabasoglu G,et al. Mechanisms governing interannual variability of upper-ocean temperature in a global ocean hindcast simulation[J]. Journal of Physical Oceanography, 2007, 37(7): 1 918-1 939.
[12]Cummins P F, Freeland H J. Variability of the North Pacific Current and its bifurcation[J].Progress in Oceanography, 2007, 75(5): 253-265.
[13]Yeh S W, Kang Y J, Noh Y, et al. The North Pacific climate transitions of the winters of 1976/77 and 1988/89[J].Journal of Climate,2011, 24(4):1 170-1 183.
[14]Hare S R, Mantua N J. Empirical evidence for North Pacific regime shifts in 1977 and 1989[J].Progress of Oceanography,2000, 47(2/4):103-145.
[15]Chhak K, Di Lorenzo E. Forcing of low-frequency ocean variability in the Northeast Pacific[J].Journal of Climate, 2009, 22(5): 1 255-1 276.
[16]Trenberth K E, Hurrell J W. Decadal Climate Variations in the Pacific, National Research Council, Natural Climate Variability on Decade-to-Century Time Scales[M]. Washington DC: National Academy Press, 1995:472-481.
[17]Schneider N, Cornuelle B D. The forcing of the Pacific decadal oscillation[J]. Journal of Climate,2005, 18(21): 4 355-4 373.
[18]Walker G T, Bliss E W. World weather V[J].Memoirs of the Royal Meteorological Society, 1932, 4(36): 53-84.
[19]Rogers J C. The North Pacific oscillation[J].Journal of Climate,1981, 1(1): 39-57.
[20]Qiu B, Chen S M. Eddy-mean flow interaction in the decadally modulating Kuroshio extension system[J].Deep-Sea Research Ⅱ, 2010, 57(13/14): 1 098-1 110.
[21]Furtado J C, Di Lorenzo E, Schneider N, et al. North Pacific decadal variability and climate change in the IPCC AR4 models[J]. Journal of Climate,2011,24(12):3 049-3 067.
[22]Li Chun. Variation of Wind-driven Oceanic Gyre in the North Pacific and Its Feedback to Atmospheric Circulation[D]. Qingdao: Ocean University of China, 2010.[李春. 北太平洋风生环流变异及其对大气环流的反馈[D]. 青岛:中国海洋大学, 2010.]
[23]Alexander M A, Bladé I, Newwan M, et al. The atmospheric bridge: The influence of ENSO teleconnections on air-sea interaction over the global oceans[J].Journal of Climate,2002, 15(16): 2 205-2 231.
[24]Newman M, Compo G P, Alexander M A. ENSO-forced variability of the Pacific decadal oscillation[J]. Journal of Climate, 2003,16(23): 3 853-3 857.
[25]Deser C, Phillips A S, Hurrell J W. Pacific interdecadal climate variability:Linkages between the tropics and North Pacific during boreal winter since 1900[J]. Journal of Climate, 2004, 17(16): 3 109-3 124.
[26]Vimont D J. The contribution of the interannual ENSO cycle to the spatial pattern of decadal ENSO-like variability[J]. Journal of Climate,2005, 18(12): 2 080-2 092.
[27]Alexander M A, Matrosova L, Pemland C, et al. Forecasting Pacific SSTs: Linear inverse model predictions of the PDO[J].Journal of Climate, 2008, 21(2): 385-402.
[28]Vimont D J, Wallace J M, Battisti D S. The seasonal footprinting mechanism in the Pacific: Implications for ENSO[J]. Journal of Climate,2003, 16(16): 2 668-2 675.
[29]Anderson B T. Tropical Pacific sea-surface temperatures and preceding sea level pressure anomalies in the subtropical North Pacific[J].Journal of Geophysical Research-Atmospheres,2003, 108(D23):18.
[30]Kao H Y, Yu J Y. Contrasting eastern-Pacific and central-Pacific types of El Niño[J]. Journal of Climate, 2009, 22(3): 615-632.
[31]Di Lorenzo E, Cobb K M, Furtado J C, et al. Central Pacific El Niño and decadal climate change in the North Pacific[J]. Nature Geoscience, 2010, 3(11): 762-765.
[32]Di Lorenzo E, Schneider N, Cobb K M, et al. ENSO and the North Pacific Gyre Oscillation:An Integrated View of Pacific Decadal Dynamics[R].Atlanta GA: The 90th American Meteorological Society Annual Meeting,2010.
[33]Yu J Y, Kao H Y, Lee T. Subtropics-related interannual sea surface temperature variability in the equatorial central Pacific[J].Journal of Climate,2010, 23(11): 2 869-2 884.
[34]Yu J Y, Kim S T. Relationships between extratropical sea level pressure variations and the central-Pacific and eastern-Pacific types of ENSO[J].Journal of Climate, 2011,24(3):708-720.
[35]Linkin M E, Nigam S. The north pacific oscillation-west Pacific teleconnection pattern: Mature-phase structure and winter impacts[J].Journal of Climate, 2008, 21(9): 1 979-1 997.
[36]Yeh S W, Kug J S, Dewitte B, et al. El Niño in a changing climate[J]. Nature, 2009, 461: 511-514.
[37]Ceballos L, Di Lorenzo E, Hoyos C D. North Pacific Gyre Oscillation synchronizes climate fluctuations in the eastern and western boundary systems[J].Journal of Climate,2009, 22(19): 5 163-5 174.
[38]Taguchi B, Xie S P, Schneider N, et al. Decadal variability of the Kuroshio extension: Observations and an eddy-resolving model hindcast[J].Journal of Climate,2007, 20(11):2 357-2 377.
[39]Miller A J, White W B, Cayan D R. North Pacific thermocline variations on ENSO timescales[J].Journal of Physical Oceanography, 1997, 27(9): 2 023-2 039.
[40]Qiu B, Schneider N, Chen S M. Coupled decadal variability in the North Pacific: An observationally constrained idealized model[J].Journal of Climate,2007, 20(14): 3 602-3 620.
[41]Qiu B. Kuroshio extension variability and forcing of the Pacific decadal oscillations: Responses and potential feedback[J].Journal of Physical Oceanography, 2003, 33(12): 2 465-2 482.
[42]Zhu Yimin, Yang Xiuqun. Relationships between Pacific Decadal Oscillation(PDO) and climate variabilities in China[J]. Acta Meteorological Sinica,2003, 61(6): 641-654.[朱益民, 杨修群.太平洋年代际振荡与中国气候变率的联系[J].气象学报, 2003, 61(6): 641-654.]
[43]Yang Qiuming. Interdecadal variations of relationships between summer rainfall in Changjiang and Huaihe valleys and SST in Indian Ocean[J].Journal of Tropical Oceanography,2005, 24(5): 31-42.[杨秋明. 夏季江淮地区雨量与印度洋海温联系的年代际变化[J]. 热带海洋学报, 2005, 24(5):31-42.]
[44]Wei Fengying, Zhang Ting. Oscillation charateristics of summer precipitation in the Huaihe River valley and relevantclimate background[J].Science in China (Series D),2009, 39(10): 1 360-1 374.[魏凤英, 张婷.淮河流域夏季降水的振荡特征及其与气候背景的关系[J]. 中国科学:D辑, 2009, 39(10): 1 360-1 374.]
[45]Yoon J, Yeh S W. Influence of the Pacific Decadal Oscillation on the relationship between El Niño and the Northeast Asian summer monsoon[J].Journal of Climate,2010, 23(17): 4 525-4 537.
[46]Mao J, Chan J C L, Wu G. Interannual variations of early summer monsoon rainfall over South China under different PDO backgrounds[J].International Journal of Climatology,2011,31(6):847-862
/
| 〈 |
|
〉 |
甘公网安备62010202000687
