北太平洋Rossby波研究进展

doi:10.11867/j.issn.1001-8166.2009.11.1219

系统地阐述了北太平洋Rossby波在卫星观测、理论扩展及模型应用3个方面的研究成果。随着卫星观测技术的发展，明显地探测到海表面信号的Rossby波特征，且观测到波速在热带外大于自由Rossby波理论值。为解释这个波动加速现象，在自由Rossby波理论的基础上，考虑了大气强迫、非静止基流及海底地形等因子的作用，使得Rossby波的波动理论得到了扩展。而关于风应力强迫Rossby波的线性理论模型主要有3类：一阶斜压Rossby波模型、局地Ekman抽吸模型和Sverdrup平衡模型。这些模型被广泛地应用到北太平洋海表面高度和温度/密度跃层深度等要素变化的机理研究中，得到了不同的模型在大洋的不同区域有不同的作用等结论。最后，对线性Rossby波研究存在的问题进行了初步探讨，提出了需要进一步解决的新课题。

关键词: 北太平洋, Rossby波, 卫星观测, 理论扩展, 动力模型

The baroclinic Rossby waves took a substantial role in the adjustment of dynamic processes in global ocean. The studies of the Rossby waves in the North Pacific Ocean were reviewed, focusing on the satellite observing, theories extended and models applied. Beside the satellite altimeter data detecting the ubiquitous Rossby waves in ocean, other oceanic surface signals (sea surface temperature, ocean color and sea surface salinity) could also reflect the planetary waves′ characteristics, which suggested that the Rossby waves not only functioned in dynamics, but also acted on thermodynamics and biology. Moreover, at mid and high-latitude, the phase speeds of the observed waves were faster than those given by standard linear Rossby waves theory. The two extended theories explaining the speedup phenomena were presented. First, the Rossby waves were forced by wind stress and were coupled with the overlying atmosphere, so were not free. Second, the ocean′s background state was not at rest, and also the ocean had a varying bottom. The linear dynamic models forced by wind stress were introduced, including the first baroclinic Rossby waves model, local Ekman pumping model and Sverdrup balance model. In particular, the applications of these models in sea surface height and thermocline/pycnocline depth variability in the North Pacific Ocean were described in detail. Finally, the existing questions of linear Rossby waves theory were discussed, and outstanding issues were advanced.

Key words: North Pacific Ocean, Baroclinic Rossby waves, Satellite observing, Theory extended, Dynamic models

中图分类号:

P731.2

[1]Hough S. On the application of harmonic analysis to the dynamical theory of the tides, Part I. On Laplace′s oscillations of the first species′, and on the dynamics of ocean currents[J].Philosophical Transaction of the Royal Society of London,1897, 189A: 201-257.
[2]Chelton D B, Schlax M G. Global observations of oceanic Rossby wave[J].Science,1996, 272: 234-238.
[3]Philander S G H. Forced oceanic waves[J].Reviews of Geophysics and Space Physics,1978, 16: 15-46.
[4]Tomczak M, Godfrey J S. Regional oceanography: An introduction[DB/OL].http:∥www.es.flinders.edu.au/~mattom/regoc/pdfversion.html, 2001.
[5]Rossby C, Collaborators. Relations between variations in the intensity of the zonal circulation of the atmosphere and the displacements of the semi-permanent centers of action[J].Journal Marine Research,1939, 2: 35-55.
[6]Rossby C. Planetary flow patterns in the atmosphere[J].Quarterly Journal of the Royal Meteorological Society,1940, 66:68-97.
[7]Gill A E. Atmosphere Ocean Dynamics[M]. New York: Academic Press, 1982. 
[8]Challenor P G, Cipollini P, Cromwell D. Use of the 3-D Radon transform to examine the properties of oceanic Rossby waves[J].Journal of Atmospheric and Oceanic Technology,2001, 18: 1 558-1 566.
[9]Chelton D B, de Szoeke R A, Schlax M G, et al. Geographical variability of the first baroclinic Rossby radius of deformation[J].Journal of Physical Oceanography,1998, 28: 433-460.
[10]Fan Haimei, Zhang QingHua, Li Bingrui, et al. Adjustment of the first baroclinic Rossby wave propagating in global ocean[J].Advances in Marine Science,2007, 25(1): 15-19.[范海梅，张庆华，李丙瑞，等. 第一斜压Rossby波在大洋传播中的调整[J]. 海洋科学进展，2007，25 (1): 15-19.]
[11]Wunsch C. The vertical partition of oceanic horizontal kinetic energy[J].Journal of Physical Oceanography,1997, 27,:1 770-1 794.
[12]Codiga D L, Cornillon P. Effects of geographic variation in vertical mode structure on the sea surface topography, energy, and wind forcing of baroclinic Rossby waves[J].Journal of Physical Oceanography,2003, 33: 1 219-1 230.
[13]Fu L L, Chelton D B. Large-scale ocean circulation[C]∥Fu L-L, Cazenave A, eds. Satellite Altimetry and Earth Sciences: A Handbook of Techniques and Applications. San Diego: Academic Press, 2001: 133-169.
[14]Cipollini P, Cromwell D, Jones M S, et al. Concurrent altimeter and infrared observations of Rossby wave propagation near 34°N in the Northeast Atlantic[J].Geophysical Research Letter,1997, 24: 889-892.
[15]Polito P S, Cornillon P. Long baroclinic Rossby waves detected by TOPEX/POSEIDON[J].Journal of Geophysical Research,1997, 102: 3 215-3 235.
[16]Cipollini P, Quartly G D, Challenor P G, et al. Remote sensing of extra-equatorial planetary waves in the oceans[C]∥Manual of Remote Sensing, Volume 6: Remote Sensing of Marine Environment, chapter 3.Bethesda:American Society for Photogrammetry and Remote Sensing, 2006: 61-84.
[17]Chen Haiying, Qiao Fangli, Wang Yonggang. Zonal propagation velocity distribution characteristics of oceanic Rossby waves[J].Advances in Marine Science,2003, 21(4): 387-392.[陈海英，乔方利，王永刚.大洋Rossby波动纬向传播速度的分布特征[J]. 海洋科学进展，2003，21（4）：387-392.]
[18]Osychny V, Cornillon P. Properties of Rossby waves in the North Atlantic estimated from satellite data[J].Journal of Physical Oceanography,2004, 34: 61-76.
[19]Lin X, Wu D, Li Q, et al. An amplification mechanism of intraseasonal long Rossby wave in subtropical ocean[J].Journal of Oceanography,2005, 61: 369-378.
[20]Hill K L, Robinson I S, Cipollini P. Propagation characteristics of extratropical planetary waves observed in the ATSR global sea surface temperature record[J].Journal of Geophysical Research,2000, 105: 21 927-21 945.
[21]Killworth P D, Chelton D B, deSzoeke R A. The speed of observed and theoretical long extratropical planetary wave[J].Journal of Physical Oceanography,1997, 27: 1 946-1 966.
[22]Cipollini P, Cromwell D, Challenor P G, et al. Rossby waves detected in global ocean colour data[J]. Geophysical Research Letters,2001, 28: 323-326.
[23]Uz B M, Yoder J A, Osychny V. Pumping of nutrients to ocean surface waters by the action of propagating planetary waves[J].Nature,2001, 409: 597-600.
[24]Killworth P D, Cipollini P, Uz B M, et al. Physical and biological mechanisms for planetary waves observed in sea-surface chlorophyll[J].Journal of Geophysical Research,2004, 109(C7),CO7002,doi:10.1029/2003JC001768.
[25]Sakamoto C M, Karl D M, Jannasch H W, et al. Influence of Rossby waves on nutrient dynamics and the plankton community structure in the North Pacific subtropical gyre[J].Journal of Geophysical Research,2004, 109, C05032, doi:10.1029/2003JC001976.
[26]Heffner D M, Subrahmanyam B, Shriver J F. Indian Ocean Rossby waves detected in HYCOM sea surface salinity[J].Geophysical Research Letters,2008, 35, L03605, doi:10.1029/2007GL032760.
[27]Chu P C, Ivanov L M, Melnichenko O V, et al. On long baroclinic Rossby waves in the tropical North Atlantic observed from profiling floats[J].Journal of Geophysical Research,2007, 112, C05032, doi:10.1029/2006JC003698.
[28]Polito P S, Sato O T, Wainera I. Height variability from the MIROC IPCC model for the 20th century compared to that of the TOPEX/POSEIDON altimeter[J].Ocean Modelling,2008, 24: 73-91.
[29]White W. Observations of long Rossby waves in the northern tropical Pacific [J].Journal of Physical Oceanography,1977, 7: 50-61.
[30]Meyers G. On the annual Rossby wave in the tropical North Pacific Ocean[J].Journal of Physical Oceanography,1979, 9: 664-673.
[31]Qiu B, Miao W, Muller P. Propagation and decay of forced and free Rossby waves in off-equatorial ocean[J].Journal of Physical Oceanography,1997, 27: 2 405-2 417.
[32]Leonardi A P, Morey S L, O′Brien J J. Interannual variability in the eastern subtropical North Pacific Ocean[J].Journal of Physical Oceanography,2002, 32: 1 824-1 837.
[33]White W B, Chao Y, Chang K. Coupling of biennial oceanic Rossby waves with the overlying atmosphere in the Pacific basin[J].Journal of Physical Oceanography, 1998, 28: 1 236-1 251.
[34]Tailleux R, Mc Williams J C. Acceleration, creation, and depletion of wind-driven, baroclinic Rossby waves over an ocean ridge[J].Journal of Physical Oceanography,2000, 30: 2 186-2 213.
[35]Tailleux R, Mc Williams J C. The effect of bottom pressure decoupling on the speed of extratropical, baroclinic Rossby waves[J].Journal of Physical Oceanography,2001,31: 1 461-1 476.
[36]LaCasce J H, Pedlosky J. The instability of Rossby basin modes and the oceanic eddy field[J].Journal of Physical Oceanography,2004, 34: 2 027-2 041.
[37]Isachsen P E, LaCasce J H, Pedlosky J. Rossby wave instability and apparent phase speeds in large ocean basins[J].Journal of Physical Oceanography,2007, 37: 1 177-1 191.
[38]Frankignoul C, Müller P, Zorita E. A simple model of the decadal response of the ocean to stochastic wind stress forcing[J].Journal of Physical Oceanography,1997, 27: 1 533-1 546.
[39]White W B. Evidence for coupled Rossby waves in the annual cycle of the Indo-Pacific Ocean[J].Journal of Physical Oceanography,2001, 31: 2 944-2 957.
[40]White W B. Tropical coupled Rossby waves in the Pacific ocean atmosphere system[J].Journal of Physical Oceanography,2000, 30: 1 245-1 264.
[41]Farneti R. Coupled interannual Rossby waves in a quasigeostrophic ocean atmosphere model[J].Journal of Physical Oceanography,2007, 37: 1 192-1 214.
[42]Ferreira D, Frankignoul C, Marshall J. Coupled ocean atmosphere dynamics in a simple midlatitude climate model[J].Journal of Climate,2001, 14: 3 704-3 723.
[43]de Szoeke R, Chelton D B. The modification of long planetary waves by homogeneous potential vorticity layers[J].Journal of Physical Oceanography,1999, 29: 500-511.
[44]Dewar W K. On “too-fast” baroclinic planetary waves in the general circulation[J].Journal of Physical Oceanography,1998, 28: 1 739-1 758.
[45]Liu Z. Planetary wave modes in the thermocline: Non-Doppler-shift mode, advective mode and Green mode[J].Quarterly Journal of the Royal Meteorological Society,1999, 125: 1 315-1 339.
[46]Yang H. Evolution of long planetary wave packets in a continuously stratified ocean[J].Journal of Physical Oceanography,2000, 30: 2 111-2 123.
[47]Dewar W K, Morris M Y. On the propagation of baroclinic waves in the general circulation[J].Journal of Physical Oceanography,2000, 30: 2 637-2 649.
[48]Killworth P D, Blundell J R. Large-scale propagating disturbances: Approximation by vertical normal modes[J].Journal of Physical Oceanography,2001, 31: 2 852-2 870.
[49]Colin de Verdière, Tailleux A R. The interaction of a baroclinic mean flow with long Rossby waves[J].Journal of Physical Oceanography,2005, 35: 865-879.
[50]Killworth P D, Blundell J R. The effect of bottom topography on the speed of long extra-tropical planetary waves[J].Journal of Physical Oceanography,1999, 29: 2 689-2 710.
[51]Tailleux R. Comments on “The effect of bottom topography on the speed of long extratropical planetary waves”[J].Journal of Physical Oceanography,2003, 33:1 536-1 541.
[52]Tailleux R. The quasi-nondispersive regimes of long extratropical baroclinic Rossby waves over (slowly varying) topography[J].Journal of Physical Oceanography,2006, 36: 104-121.
[53]Maharaj A M, Cipollini P, Holbrook N J. Observed variability of the South Pacific westward sea level anomaly signal in the presence of bottom topography[J].Geophysical Research Letters,2005, 32(4),L04611,doi:10.1029/2004GL020966.
[54]Killworth P D, Jeffrey R B. Long extratropical planetary wave propagation in the presence of slowly varying mean flow and bottom topography. Part I: The local problem[J].Journal of Physical Oceanography,2003, 33: 784-801.
[55]Killworth P D, Jeffrey R B. Long extratropical planetary wave propagation in the presence of slowly varying mean flow and bottom topography. Part II: Ray propagation and comparison with observations[J].Journal of Physical Oceanography,2003, 33: 802-821.
[56]Killworth P D, Blundell J R. The dispersion relation for planetary waves in the presence of mean flow and topography. Part I: Analytical theory and one-dimensional examples[J].Journal of Physical Oceanography,2004, 34: 2 692-2 711.
[57]Killworth P, Blundell J R. The dispersion relation for planetary waves in the presence of mean flow and topography. Part II: Two-dimensional examples and global results[J].Journal of Physical Oceanography,2005, 35: 2 110-2 133.
[58]Maharaj A M, Cipollini P, Holbrook N J, et al. An evaluation of the classical and extended Rossby wave theories in explaining spectral estimates of the first few baroclinic modes in the South Pacific Ocean[J].Ocean Dynamics,2007,57(3):173-187.
[59]Lecointre A, Penduff T, Cipollini P, et al. Depth dependence of westward-propagating North Atlantic features diagnosed from altimetry and a numerical 1/6 model[J].Ocean Science,2008, 4: 99-113.
[60]Clarke A J, Dottori M. Planetary wave propagation off California and its effect on zooplankton[J].Journal of Physical Oceanography,2008, 38: 702-714.
[61]Zang X, Wunch C. The observed dispersion relationship for North Pacific Rossby wave motions[J].Journal of Physical Oceanography,1999, 29: 2 183-2 190.
[62]Polito P S, Liu W T. Global characterization of Rossby waves at several spectral bands[J].Journal of Geophysical Research,2003, 108(C1), 3018, doi:10.1029/2000JC000607.
[63]Saenko O A. Influence of global warming on baroclinic Rossby radius in the ocean: A model intercomparison[J].Journal of Climate,2006, 19: 1 354-1 360.
[64]Fyfe J C, Saenko O A. Anthropogenic speed-up of oceanic planetary waves[J].Geophysical Research Letters,2007, 34, L10706, doi:10.1029/2007GL029859.
[65]Polito P S, Sato O T. Global interannual trends and amplitude modulations of the sea surface height anomaly from the TOPEX/Jason-1 altimeters[J].Journal of Climate,2008, 21: 2 824-2 834.
[66]Kessler W S. Observation of long Rossby waves in the northern tropical Pacific[J].Journal of Geophysical Research,1990, 95: 5 183-5 219.
[67]Jin F F. A theory of interdecadal climate variability of the North Pacific ocean atmosphere system[J].Journal of Climate,1997, 10: 1 821-1 835.
[68]Kwon Y O, Deser C. North Pacific decadal variability in the Community Climate System Model version 2[J].Journal of Climate,2007, 20: 2 416-2 433.
[69]Zhong Y, Liu Z, Jacob R. Origin of Pacific multidecadal variability in Community Climate System Model, Version 3 (CCSM3): A combined statistical and dynamical assessment[J].Journal of Climate,2008, 21: 114-133.
[70]Miller A J, White W B, Cayan D R. North Pacific thermocline variations on ENSO timescales[J].Journal of Physical Oceanography,1997, 27: 2 023-2 039.
[71]Fu L L, Qiu B. Low-frequency variability of North Pacific Ocean: The roles of boundary-driven and wind-driven baroclinic Rossby waves[J].Journal of Geophysical Research,2002, 107 (C12), 3220, doi: 10.1029/2001JC001131.
[72]Vega A, du-Penhoat Y, Dewitte B, et al. Equatorial forcing of inter-annual Rossby waves in the eastern South Pacific[J].Geophysical Research Letters,2003, 30, 1197, doi: 10.1029/2002GL015886.
[73]Hasselmann K. Stochastic climate models. Part 1. Theory[J].Tellus,1976, 28: 473-485.
[74]Frankignoul C, Hasselmann K. Stochastic climate models. Part II: Application to sea-surface temperature anomalies and thermocline variability[J].Tellus,1977, 29: 284-305.
[75]Shi Shaoying, Liu Shida, Fu Zuntao, et al. The characteristic analysis of weather and climate time series[J].Chinese Journal of Geophysics,2005, 48(2): 259-264.[时少英，刘式达，付遵涛，等.天气和气候的时间序列特征分析[J]. 地球物理学报，2005, 48(2)：259-264.]
[76]Liu Shida, Shi Shaoying, Liu Shikuo, et al. Bridge between weather and climate: Fractional derivative[J].Meteorological Science and Technology,2007, 35(1): 15-19.[刘式达，时少英，刘式适，等. 天气和气候之间的桥梁——分数阶导数[J]. 气象科技，2007, 35(1): 15-19.]
[77]Lagerloef G S E. Interdecadal variations in the Alaska Gyre[J].Journal of Physical Oceanography,1995, 25: 2 242-2 258.
[78]Willebrand J, Philander S G H, Pacanowski R C. The oceanic response to large-scale atmospheric disturbances[J].Journal of Physical Oceanography,1980, 10: 411-429.
[79]Miller A J, Cayan D R, White W B. A westward-intensified decadal change in the North Pacific thermocline and gyre-scale circulation[J].Journal of Climate,1998, 11: 3 112-3 127.
[80]Deser C, Alexander M A, Timlin M S. Evidence for a wind-driven intensification of the Kuroshio Current Extension from the 1970s to the 1980s[J].Journal of Climate,1999, 12: 1 697-1 706.
[81]Jiang Hua, Wang Hui, Zhu Jiang, et al. The study of the relation between the North Pacific Ocean subtropical gyre meridional transport and Sverdrup transport[J].Chinese Science Bulletin,2006, 51(2): 200-203.[姜华，王辉，朱江，等. 北太平洋副热带环流的经向向输送与Sverdrup输送关系研究[J]. 科学通报，2006，51(2): 200-203.]
[82]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: 2 357-2 377.
[83]Ceballos L I, Di Lorenzo E, Hoyos C D. North Pacific Gyre Oscillation synchronizes climate fluctuations in the eastern and western boundary systems[J].Journal of Climate,2009,22:5 163-5 174.
[84]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.
[85]Nonaka M, Nakamura H, Tanimoto Y, et al. Decadal variability in the Kuroshio Oyashio Extension simulated in an eddy-resolving OGCM[J].Journal of Climate,2006, 19:1 970-1 989.
[86]Nonaka M, Nakamura H, Tanimoto Y, et al. Interannual-to-decadal variability in the Oyashio and its influence on temperature in the subarctic frontal zone: An eddy-resolving OGCM simulation[J].Journal of Climate,2008, 21: 6 283-6 303.
[87]Cummins P F, Lagerloef G S E. Wind-driven interannual variability over the northeast Pacific Ocean[J].Deep-Sea Research,2004, 51: 2 105-2 121.
[88]Qiu B. Large-scale variability in the midlatitude subtropical and subpolar North Pacific Ocean: Observations and causes[J].Journal of Physical Oceanography,2002, 32: 353-375.
[89]Qiu B. Kuroshio Extension variability and forcing of the Pacific decadal oscillations: Responses and potential feedback[J].Journal of Physical Oceanography,2003, 33: 2 465-2 482.
[90]Qiu B, Chen S. Eddy-mean flow interaction in the decadally-modulating Kuroshio Extension system[J].Deep-Sea Research,2009(in press).
[91]Qiu B, Chen S. Variability of the Kuroshio Extension jet, recirculation gyre and mesoscale eddies on decadal timescales[J].Journal of Physical Oceanography,2005, 35: 2 090-2 103.
[92]Chen S, Qiu B. Annual variations in sea surface height northeast of the Hawaiian Islands[J].Geophysical Research Letters,2006, 33, L17612, doi:10.1029/2006GL027005.
[93]Capotondi A, Alexander M A, Deser C. Why are there Rossby wave maxima in the Pacific at 10°S and 13°N?[J].Journal of Physical Oceanography,2003, 33: 1 549-1 563.
[94]Capotondi A, Alexander M A. Rossby waves in the tropical North Pacific and their role in decadal thermocline variability[J].Journal of Physical Oceanography,2001, 31: 3 496-3 515.
[95]Lysne J, Deser C. Wind-driven thermocline variability in the Pacific: A model data comparison[J].Journal of Climate,2002, 15: 829-845.
[96]Seager R, Kushnir Y, Naik N, et al. Wind-driven shifts in the latitude of the Kuroshio Oyashio Extension and generation of SST anomalies on decadal timescales[J]. Journal of Climate,2001, 14: 4 249-4 265.
[97]Schneider N, Miller A J. Predicting western North Pacific Ocean climate[J]. Journal of Climate, 2001, 14: 3 997-4 002.
[98]Schneider N, Miller A J, Pierce D W. Anatomy of North Pacific decadal variability[J].Journal of Climate,2002, 15: 586-605.
[99]Cummins P F, Lagerloef G S E. Low-frequency pycnocline depth variability at ocean weather station P in the northeast Pacific[J].Journal of Physical Oceanography,2002, 32: 3 207-3 215.
[100]Capotondi A, Alexander M A, Deser C, et al. Low-frequency pycnocline variability in the northeast Pacific[J].Journal of Physical Oceanography,2005, 35: 1 403-1 420.
[101]Capotondi A, Combes V, Alexander M A, et al. Low-frequency variability in the Gulf of Alaska from coarse and eddy-permitting ocean models[J].Journal of Geophysical Research,2009, 114, C01017, doi:10.1029/2008JC004983.
[102]Kawabe M. Calculation of interannual variations of sea level in the subtropical North Pacific[J].Journal of Oceanography,2000, 56: 691-706.
[103]Firing Y L, Merrifield M A, Schroeder T A, et al. Interdecadal sea level fluctuations at Hawaii[J].Journal of Physical Oceanography,2004, 34: 2 514-2 524.
[104]Killworth P D, Blundell J R. Planetary wave response to surface forcing and to instability in the presence of mean flow and topography[J].Journal of Physical Oceanography,2007, 37: 1 297-1 320.
[105]Chelton D B, Schlax M G, Samelson R M, et al. Global observations of large oceanic eddies[J].Geophysical Research Letters,2007, 34, L15606, doi:10.1029/2007GL030812.
[106]Tulloch R, Marshall J, Smith K S. Interpretation of the propagation of surface altimetric observations in terms of planetary waves and geostrophic turbulence[J].Journal of Geophysical Research,2009, 114, C02005, doi:10.1029/2008JC005055.
[107]Maximenko N A, Bang B, Sasaki H. Observational evidence of alternating zonal jets in the world ocean[J].Geophysical Research Letters,2005, 32, L12607, doi:10.1029/2005GL022728.
[108]Maximenko N A, Melnichenko O V, Niiler P P, et al. Stationary mesoscale jet-like features in the ocean[J].Geophysical Research Letters,2008, 35, L08603, doi:10.1029/2008GL033267.
[109]Richards K J, Maximenko N A, Bryan F O, et al. Zonal jets in the Pacific Ocean[J].Geophysical Research Letters,2006, 33, L03605, doi:10.1029/2005GL024645.
[110]Latif M, Barnett T P. Causes of decadal climate variability over the North Pacific and North America[J].Science,1994, 266: 634-637.
[111]Latif M, Barnett T P. Decadal climate variability over the North Pacific and North America: Dynamics and predictability[J].Journal of Climate,1996, 9: 2 407-2 423.
[112]Zhong Y, Liu Z. On the mechanism of Pacific multidecadal climate variability in CCSM3: The role of subpolar North Pacific Ocean[J].Journal of Climate,2009,39:2 052-2 076.

[1]	由德方, 王汝建, 肖文申. 北太平洋中部赫斯海隆(Hess Rise) 晚第四纪以来生源组分与粉尘输入的关系及其变化机制 ^*[J]. 地球科学进展, 2018, 33(11): 1203-1214.
[2]	尹碧文, 任福民, 李国平. 1951—2014年西北太平洋双台风活动气候特征研究[J]. 地球科学进展, 2017, 32(6): 643-650.
[3]	容新尧, 刘征宇, 段晚锁. 耦合模式中北太平洋和北大西洋海表面温度年代际可预报性和预报技巧的季节依赖性[J]. 地球科学进展, 2017, 32(4): 382-395.
[4]	徐凯, 姚志刚, 韩志刚, 赵增亮, 方涵先. 临近空间重力波强扰动的卫星观测研究进展[J]. 地球科学进展, 2017, 32(1): 66-74.
[5]	谢榕, 刘亚文, 李翔翔. 大数据环境下卫星对地观测数据集成系统的关键技术[J]. 地球科学进展, 2015, 30(8): 855-862.
[6]	韩钦臣, 康建成, 王国栋, 朱炯. 基于海洋分析资料的吕宋海峡水交换的月际变化特征[J]. 地球科学进展, 2015, 30(5): 609-619.
[7]	张韧, 洪梅, 刘科峰, 朱伟军. 基于副热带高压异常活动个例的动力模型重构与变异特性剖析[J]. 地球科学进展, 2014, 29(11): 1250-1261.
[8]	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.
[9]	陆日宇,富元海. 夏季东亚和西北太平洋地区的气候变异及其机理[J]. 地球科学进展, 2009, 24(2): 123-131.
[10]	翟世奎,李怀明,于增慧,于新生. 现代海底热液活动调查研究技术进展[J]. 地球科学进展, 2007, 22(8): 769-776.
[11]	吴立新,刘秦玉,胡敦欣,李崇银,左军成,俞永强,孙澈,王启. 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[J]. 地球科学进展, 2007, 22(12): 1224-1230.
[12]	陈光华,黄荣辉. 西北太平洋热带气旋和台风活动若干气候问题的研究[J]. 地球科学进展, 2006, 21(6): 610-616.
[13]	刘宇,管玉平,林一骅. 大洋热盐环流研究的一个焦点：北太平洋是否有深水形成[J]. 地球科学进展, 2006, 21(11): 1185-1192.

阅读次数

全文

摘要

Rossby Waves in the North Pacific Ocean: A Review