Intraseasonal Variability of Surface Salinity in the Eastern Tropical Pacific Associated With Mesoscale Eddies

Hasson, Audrey; Farrar, J. Thomas; Boutin, Jacqueline; Bingham, Frederick M.; Lee, Tong

doi:10.1029/2018jc014175

Cited by 21 publications

(17 citation statements)

References 48 publications

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“…The theoretical meridional Ekman current is a reasonably good match to the observed layer-averaged meridional current during the trade wind season of January–May ( Figure 6 , lower panel). During the January–June period, the fluctuations of the observed meridional velocity around the theoretical Ekman current at periods of one to two months are likely associated with the intraseasonal eddies that are prevalent in this region ( Farrar and Weller, 2006 ; Hasson et al, in press ). The agreement of the theoretical northward Ekman current and the observed meridional velocity is notably worse during September–November 2016 and from September 2017 to the end of the record—it is not clear why this happens, but the explanation could involve intraseasonal eddies or some other dynamics associated with the NEC/NECC current system.…”

Section: Discussionmentioning

confidence: 99%

“…The westward-flowing North Equatorial Current (NEC) and eastward-flowing North Equatorial Counter Current (NECC) are also potentially major influences. The 10°N site is in between the climatological average locations of the NECC (5°–8°N) and NEC (10°–15°N), but the two currents move north and south and vary in intensity seasonally with the ITCZ and trade winds (e.g., Farrar and Weller, 2006 ; Hasson et al, in press ).…”

Section: The Eastern Pacific Fresh Pool and Important Hypotheses Of Tmentioning

confidence: 99%

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On the Factors Driving Upper-Ocean Salinity Variability at the Western Edge of the Eastern Pacific Fresh Pool

Farrar

Plueddemann

2019

Oceanog

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Section: Discussionmentioning

confidence: 99%

Section: The Eastern Pacific Fresh Pool and Important Hypotheses Of Tmentioning

confidence: 99%

On the Factors Driving Upper-Ocean Salinity Variability at the Western Edge of the Eastern Pacific Fresh Pool

Farrar

Plueddemann

2019

Oceanog

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“…The increased spatial coverage provides opportunities for applying SMAP data for high resolution studies. SMAP now is widely used in ocean (Hasson et al, 2019;Vazquez-Cuervo et al, 2019) and river plume (Brokaw et al, 2019;Kida et al, 2019;Mathur et al, 2019) studies, although there are uncertainties in coastal regions. Standard deviation errors near the coasts are 10 times larger than those on oceans (Martin et al, 2019).…”

Section: Temperature and Salinitymentioning

confidence: 99%

Modulation of Shelf Circulations Under Multiple River Discharges in the East China Sea

Wang

2021

JGR Oceans

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Marginal seas are primary fields for land-ocean interaction. Water mass and dissolved or suspended substances from both riverine and oceanic sources are transported and mixed, producing a highly dynamic and heavily productive area. It is reported that shelf ecosystems (tropical and non-tropical) primary productions are 8.37 × 10 15 gCyr −1 that supports 59.5% of primary production required to sustain world fisheries (Pauly & Christensen, 1995). Meanwhile, the continental shelves provide 90% of the global marine fishery capture, despite it covers only 7% of the global ocean area (Pauly et al., 2002). Dynamic processes determine the property and transport of water mass, thus play a substantial role in sustaining biogeochemical and ecological cycles. Riverine and oceanic waters are confluent in the marginal sea, with contrasting densities. The riverine freshwater produces a low-salinity plume that floats over ambient sea or extends along the coast as a buoyant coastal current (Yankovsky & Chapman, 1997), which is regulated by various external forcings such as wind, tides, and shelf circulations (

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“…As this study started, individual satellite SSS is capable of resolving the upper register of the mesoscale spectrum (spatial scale of 50–500 km and temporal scale of 10–100 days) (e.g., Hasson et al., 2019; Huang et al., 2021; Kolodziejczyk et al., 2021; Lin et al., 2019; Melnichenko et al., 2021; Olivier et al., 2020). These scales play an important role in the mixing and exchanges of water masses close to fronts, as a result of ocean circulation and atmospheric fluxes.…”

Section: Introductionmentioning

confidence: 99%

Satellite‐Based Sea Surface Salinity Designed for Ocean and Climate Studies

et al. 2021

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Sea Surface Salinity (SSS) is an increasingly used Essential Ocean and Climate Variable. The Soil Moisture and Ocean Salinity (SMOS), Aquarius, and Soil Moisture Active Passive (SMAP) satellite missions all provide SSS measurements, with very different instrumental features leading to specific measurement characteristics. The Climate Change Initiative Salinity project (CCI + SSS) aims to produce a SSS Climate Data Record (CDR) that addresses well‐established user needs based on those satellite measurements. To generate a homogeneous CDR, instrumental differences are carefully adjusted based on in‐depth analysis of the measurements themselves, together with some limited use of independent reference data. An optimal interpolation in the time domain without temporal relaxation to reference data or spatial smoothing is applied. This allows preserving the original datasets variability. SSS CCI fields are well suited for monitoring weekly to interannual signals, at spatial scales ranging from 50 km to the basin scale. They display large year‐to‐year seasonal variations over the 2010–2019 decade, sometimes by more than ±0.4 over large regions. The robust standard deviation of the monthly CCI SSS minus in situ Argo salinities is 0.15 globally, while it is at least 0.20 with individual satellite SSS fields. r2 is 0.97, similar or better than with original datasets. The correlation with independent ship thermosalinographs SSS further highlights the CCI data set excellent performance, especially near land areas. During the SMOS‐Aquarius period, when the representativity uncertainties are the largest, r2 is 0.84 with CCI while it is 0.48 with the Aquarius original data set. SSS CCI data are freely available and will be updated and extended as more satellite data become available.

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Intraseasonal Variability of Surface Salinity in the Eastern Tropical Pacific Associated With Mesoscale Eddies

Cited by 21 publications

References 48 publications

On the Factors Driving Upper-Ocean Salinity Variability at the Western Edge of the Eastern Pacific Fresh Pool

On the Factors Driving Upper-Ocean Salinity Variability at the Western Edge of the Eastern Pacific Fresh Pool

Modulation of Shelf Circulations Under Multiple River Discharges in the East China Sea

Satellite‐Based Sea Surface Salinity Designed for Ocean and Climate Studies

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