The Western Tropical Pacific(WTP) Ocean holds the largest area of warm water(>28℃) in the world ocean referred to as the Western Pacific Warm Pool(WPWP),which modulates the regional and global climate through stro...The Western Tropical Pacific(WTP) Ocean holds the largest area of warm water(>28℃) in the world ocean referred to as the Western Pacific Warm Pool(WPWP),which modulates the regional and global climate through strong atmospheric convection and its variability.The WTP is unique in terms of its complex 3-D ocean circulation system and intensive multiscale variability,making it crucial in the water and energy cycle of the global ocean.Great advances have been made in understanding the complexity of the WTP ocean circulation and associated climate impact by the international scientific community since the 1960 s through field experiments.In this study,we review the evolving insight to the 3-D structure and multi-scale variability of the ocean circulation in the WTP and their climatic impacts based on in-situ ocean observations in the past decades,with emphasis on the achievements since 2000.The challenges and open que stions remaining are reviewed as well as future plan for international study of the WTP ocean circulation and climate.展开更多
The variation in the Indian Ocean is investigated using Hadley center sea surface temperature(SST) data during the period 1958–2010.All the first empirical orthogonal function(EOF) modes of the SST anomalies(SST...The variation in the Indian Ocean is investigated using Hadley center sea surface temperature(SST) data during the period 1958–2010.All the first empirical orthogonal function(EOF) modes of the SST anomalies(SSTA) in different domains represent the basin-wide warming and are closely related to the Pacific El Ni o– Southern Oscillation(ENSO) phenomenon.Further examination suggests that the impact of ENSO on the tropical Indian Ocean is stronger than that on the southern Indian Ocean.The second EOF modes in different domains show different features.It shows a clear east-west SSTA dipole pattern in the tropical Indian Ocean(Indian Ocean dipole,IOD),and a southwest-northeast SSTA dipole in the southern Indian Ocean(Indian Ocean subtropical dipole,IOSD).It is further revealed that the IOSD is also the main structure of the second EOF mode on the whole basin-scale,in which the IOD pattern does not appear.A correlation analysis indicates that an IOSD event observed during the austral summer is highly correlated to the IOD event peaking about 9 months later.One of the possible physical mechanisms underlying this highly significant statistical relationship is proposed.The IOSD and the IOD can occur in sequence with the help of the Mascarene high.The SSTA in the southwestern Indian Ocean persists for several seasons after the mature phase of the IOSD event,likely due to the positive wind–evaporation–SST feedback mechanism.The Mascarene high will be weakened or intensified by this SSTA,which can affect the atmosphere in the tropical region by teleconnection.The pressure gradient between the Mascarene high and the monsoon trough in the tropical Indian Ocean increases(decreases).Hence,an anticyclone(cyclone) circulation appears over the Arabian Sea-India continent.The easterly or westerly anomalies appear in the equatorial Indian Ocean,inducing the onset stage of the IOD.This study shows that the SSTA associated with the IOSD can lead to the onset of IOD with the aid of atmosphere circulation and also explains why some IOD events in the tropical tend to be followed by IOSD in the southern Indian Ocean.展开更多
Near-inertial oscillation is an important physical process transferring surface wind energy into deep ocean.We investigated the near-inertial kinetic energy(NIKE)variability using acoustic Doppler current profiler mea...Near-inertial oscillation is an important physical process transferring surface wind energy into deep ocean.We investigated the near-inertial kinetic energy(NIKE)variability using acoustic Doppler current profiler measurements from a mooring array deployed in the tropical western Pacific Ocean along 130°E at 8.5°N,11°N,12.6°N,15°N,and 17.5°N from September 2015 to January 2018.Spatial features,decay timescales,and significant seasonal variability of the observed NIKE were described.At the mooring sites of 17.5°N,15°N,and 12.6°N,the NIKE peaks occurred in boreal autumn and the NIKE troughs were observed in boreal spring.By contrast,the NIKE at 11°N and 8.5°N showed peaks in winter and troughs in summer.Tropical cyclones and strong wind events played an important role in the emergence of high-NIKE events and explained the seasonality and latitudinal characteristics of the observed NIKE.展开更多
Instability/stability in the North Equatorial Current(NEC)basin is studied based on data obtained from nine moorings deployed at 8.5°N,10.5°N,11.0°N,12.5°N,13.0°N,15.0°N,15.5°N,17.5&...Instability/stability in the North Equatorial Current(NEC)basin is studied based on data obtained from nine moorings deployed at 8.5°N,10.5°N,11.0°N,12.5°N,13.0°N,15.0°N,15.5°N,17.5°N,and 18.0°N along 130.0°E during cruises in 2015–2017.In low latitudes,the Coriolis parameter and stratifi cation ratio play important roles in NEC stability,whereas velocity shear and the layer depth ratio are important for NEC stability in high latitudes.Beneath the westward NEC,eastward zonal jets occur intermittently centered around 8.5°N,12.5°N,and 17.5°N along 130.0°E.Similar to the NEC,the main body of these zonal jets also deepens with latitude.In the boundary layer comprising the bottom NEC and upper zonal jets,the growth rate of the NEC is attributed not only to velocity shear but also to zonal jet velocity based on the longwave assumption.Based on the shortwave assumption,the growth rate is proportional to zonal jet velocity but has no relationship with velocity shear.Climatologically,the growth rate in the boundary layer is not zero at 8.5°N,12.5°N,and 13.0°N,where the velocity shear and zonal jets are larger than at other stations.The instability also occurs at the time node when the zonal jets are strong enough,although the mean zonal jets may disappear at this station.展开更多
We investigated the intraseasonal variability of equatorial Pacific subsurface temperature and its relationship with El Nino-Southern Oscillation(ENSO) using Self-Organizing Maps(SOM) analysis.Variation in intraseason...We investigated the intraseasonal variability of equatorial Pacific subsurface temperature and its relationship with El Nino-Southern Oscillation(ENSO) using Self-Organizing Maps(SOM) analysis.Variation in intraseasonal subsurface temperature is mainly found along the thermocline.The SOM patterns concentrate in basin-wide seesaw or sandwich structures along an east-west axis.Both the seesaw and sandwich SOM patterns oscillate with periods of 55 to 90 days,with the sequence of them showing features of equatorial intraseasonal Kelvin wave,and have marked interannual variations in their occurrence frequencies.Further examination shows that the interannual variability of the SOM patterns is closely related to ENSO;and maxima in composite interannual variability of the SOM patterns are located in the central Pacific during CP El Nino and in the eastern Pacific during EP El Nino.The se results imply that some of the ENSO forcing is manife sted through changes in the occurrence frequency of intraseasonal patterns,in which the change of the intraseasonal Kelvin wave plays an important role.展开更多
基金the National Natural Science Foundation of China(Nos.40890150,41730534,41776021)the Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDB42000000)+3 种基金the National Key Research and Development Program of China(No.2017YFA0603200)the Aoshan Science and Technology Innovation Project(No.2016ASKJ12)the Major Project of Science and Technology Innovation of Shandong(No.2018SDKJ01)supported by the USA National Science Foundation award 1851316。
文摘The Western Tropical Pacific(WTP) Ocean holds the largest area of warm water(>28℃) in the world ocean referred to as the Western Pacific Warm Pool(WPWP),which modulates the regional and global climate through strong atmospheric convection and its variability.The WTP is unique in terms of its complex 3-D ocean circulation system and intensive multiscale variability,making it crucial in the water and energy cycle of the global ocean.Great advances have been made in understanding the complexity of the WTP ocean circulation and associated climate impact by the international scientific community since the 1960 s through field experiments.In this study,we review the evolving insight to the 3-D structure and multi-scale variability of the ocean circulation in the WTP and their climatic impacts based on in-situ ocean observations in the past decades,with emphasis on the achievements since 2000.The challenges and open que stions remaining are reviewed as well as future plan for international study of the WTP ocean circulation and climate.
基金The National Natural Science Foundation of China under contract Nos 41106016 and 41330963the National Basic Research Program(973 Program)of China under contract No.2012CB417403
文摘The variation in the Indian Ocean is investigated using Hadley center sea surface temperature(SST) data during the period 1958–2010.All the first empirical orthogonal function(EOF) modes of the SST anomalies(SSTA) in different domains represent the basin-wide warming and are closely related to the Pacific El Ni o– Southern Oscillation(ENSO) phenomenon.Further examination suggests that the impact of ENSO on the tropical Indian Ocean is stronger than that on the southern Indian Ocean.The second EOF modes in different domains show different features.It shows a clear east-west SSTA dipole pattern in the tropical Indian Ocean(Indian Ocean dipole,IOD),and a southwest-northeast SSTA dipole in the southern Indian Ocean(Indian Ocean subtropical dipole,IOSD).It is further revealed that the IOSD is also the main structure of the second EOF mode on the whole basin-scale,in which the IOD pattern does not appear.A correlation analysis indicates that an IOSD event observed during the austral summer is highly correlated to the IOD event peaking about 9 months later.One of the possible physical mechanisms underlying this highly significant statistical relationship is proposed.The IOSD and the IOD can occur in sequence with the help of the Mascarene high.The SSTA in the southwestern Indian Ocean persists for several seasons after the mature phase of the IOSD event,likely due to the positive wind–evaporation–SST feedback mechanism.The Mascarene high will be weakened or intensified by this SSTA,which can affect the atmosphere in the tropical region by teleconnection.The pressure gradient between the Mascarene high and the monsoon trough in the tropical Indian Ocean increases(decreases).Hence,an anticyclone(cyclone) circulation appears over the Arabian Sea-India continent.The easterly or westerly anomalies appear in the equatorial Indian Ocean,inducing the onset stage of the IOD.This study shows that the SSTA associated with the IOSD can lead to the onset of IOD with the aid of atmosphere circulation and also explains why some IOD events in the tropical tend to be followed by IOSD in the southern Indian Ocean.
基金the National Natural Science Foundation of China (Nos.4177601891858101)+5 种基金the Key Research Program of Frontier SciencesCAS (No.QYZDBSSW-SYS023)the CAS-CSIRO Project Fund(No.133244KYSB20190031)the Strategic Priority Research Program of Chinese Academy of Sciences(No.XDB01000000) to HU Shijianthe National Program on Global Change and Air-Sea Interaction (No.GASI-IPOVAI-04)the National Natural Science Foundation of China (No.41976009) to LIU Lingling
文摘Near-inertial oscillation is an important physical process transferring surface wind energy into deep ocean.We investigated the near-inertial kinetic energy(NIKE)variability using acoustic Doppler current profiler measurements from a mooring array deployed in the tropical western Pacific Ocean along 130°E at 8.5°N,11°N,12.6°N,15°N,and 17.5°N from September 2015 to January 2018.Spatial features,decay timescales,and significant seasonal variability of the observed NIKE were described.At the mooring sites of 17.5°N,15°N,and 12.6°N,the NIKE peaks occurred in boreal autumn and the NIKE troughs were observed in boreal spring.By contrast,the NIKE at 11°N and 8.5°N showed peaks in winter and troughs in summer.Tropical cyclones and strong wind events played an important role in the emergence of high-NIKE events and explained the seasonality and latitudinal characteristics of the observed NIKE.
基金Supported by the Strategic Priority Research Program of the Chinese Academy of Sciences(No.XDB42010102)the Hydrographic and Meteorological Survey in the Warm Pool Area of Western Pacifi c(No.2013FY111300)+1 种基金the National Natural Science Foundation of China(No.41776021)the Foundation for Innovative Research Groups of the National Natural Science Foundation of China(No.41421005)。
文摘Instability/stability in the North Equatorial Current(NEC)basin is studied based on data obtained from nine moorings deployed at 8.5°N,10.5°N,11.0°N,12.5°N,13.0°N,15.0°N,15.5°N,17.5°N,and 18.0°N along 130.0°E during cruises in 2015–2017.In low latitudes,the Coriolis parameter and stratifi cation ratio play important roles in NEC stability,whereas velocity shear and the layer depth ratio are important for NEC stability in high latitudes.Beneath the westward NEC,eastward zonal jets occur intermittently centered around 8.5°N,12.5°N,and 17.5°N along 130.0°E.Similar to the NEC,the main body of these zonal jets also deepens with latitude.In the boundary layer comprising the bottom NEC and upper zonal jets,the growth rate of the NEC is attributed not only to velocity shear but also to zonal jet velocity based on the longwave assumption.Based on the shortwave assumption,the growth rate is proportional to zonal jet velocity but has no relationship with velocity shear.Climatologically,the growth rate in the boundary layer is not zero at 8.5°N,12.5°N,and 13.0°N,where the velocity shear and zonal jets are larger than at other stations.The instability also occurs at the time node when the zonal jets are strong enough,although the mean zonal jets may disappear at this station.
基金the National Natural Science Foundation of China (NSFC)(Nos.41976027,41976011,41730534,41476017,41576014)the Bureau of International Cooperation Chinese Academy of Sciences (No.132B61KYSB20170005)
文摘We investigated the intraseasonal variability of equatorial Pacific subsurface temperature and its relationship with El Nino-Southern Oscillation(ENSO) using Self-Organizing Maps(SOM) analysis.Variation in intraseasonal subsurface temperature is mainly found along the thermocline.The SOM patterns concentrate in basin-wide seesaw or sandwich structures along an east-west axis.Both the seesaw and sandwich SOM patterns oscillate with periods of 55 to 90 days,with the sequence of them showing features of equatorial intraseasonal Kelvin wave,and have marked interannual variations in their occurrence frequencies.Further examination shows that the interannual variability of the SOM patterns is closely related to ENSO;and maxima in composite interannual variability of the SOM patterns are located in the central Pacific during CP El Nino and in the eastern Pacific during EP El Nino.The se results imply that some of the ENSO forcing is manife sted through changes in the occurrence frequency of intraseasonal patterns,in which the change of the intraseasonal Kelvin wave plays an important role.
