Estimating thermohaline variability of the equatorial Pacific Ocean from satellite altimetry

Estimating thermohaline variability of the equatorial Pacific Ocean from satellite altimetry

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摘要 The vertical thermohaline structure in the western equatorial Pacific is examined with a Gravest Empirical Mode(GEM)diagnosis of in-situ mooring measurements. The poor GEM performance in estimating deep thermohaline variability from satellite altimetry confirms a lack of vertical coherence in the equatorial ocean. Mooring observation reveals layered equatorial water with phase difference up to 6 months between thermocline and sub-thermocline variations. The disjointed layers reflect weak geostrophy and resemble pancake structures in non-rotating stratified turbulence. A coherency theorem is then proved, stating that traditional stationary GEM represents in-phase coherent structure and can not describe vertically out-of-phase variability. The fact that stationary GEM holds both spatial and temporal coherence makes it a unique tool to diagnose vertical coherent structure in geophysical flows. The study also develops a non-stationary GEM projection that captures more than 40% of the thermohaline variance in the equatorial deep water. The vertical thermohaline structure in the western equatorial Pacific is examined with a Gravest Empirical Mode（GEM）diagnosis of in-situ mooring measurements. The poor GEM performance in estimating deep thermohaline variability from satellite altimetry confirms a lack of vertical coherence in the equatorial ocean. Mooring observation reveals layered equatorial water with phase difference up to 6 months between thermocline and sub-thermocline variations. The disjointed layers reflect weak geostrophy and resemble pancake structures in non-rotating stratified turbulence. A coherency theorem is then proved, stating that traditional stationary GEM represents in-phase coherent structure and can not describe vertically out-of-phase variability. The fact that stationary GEM holds both spatial and temporal coherence makes it a unique tool to diagnose vertical coherent structure in geophysical flows. The study also develops a non-stationary GEM projection that captures more than 40% of the thermohaline variance in the equatorial deep water.

作者 SUN Che MA Xiao

机构地区 Institute of Oceanology National Laboratory for Marine Science and Technology State Key Laboratory of Satellite Ocean Environment Dynamics

出处《Science China Earth Sciences》 SCIE EI CAS CSCD 2016年第11期2213-2222,共10页 中国科学（地球科学英文版）

基金 supported by the National Basic Research Program of China (Grant No.2012CB417400) the National Natural Science Foundation of China (Grant Nos. 41576017 & U1406401)

关键词 Equatorial Pacific TRITON buoys Satellite altimetry GEM Vertical coherence 赤道的太平洋；三重氢核浮标；卫星测高法；宝石；垂直连贯；

分类号 P715.6 [天文地球—海洋科学] P731.27

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Estimating thermohaline variability of the equatorial Pacific Ocean from satellite altimetry

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