Two decades [1992–2012] of surface wind analyses based on satellite scatterometer observations

Desbiolles, Fabien; Bentamy, Abderrahim; Blanke, Bruno; Roy, Claude; Mestas-Nuñez, Alberto M.; Grodsky, Semyon A.; Herbette, Steven; Cambon, Gildas; Maes, Christophe

doi:10.1016/j.jmarsys.2017.01.003

Cited by 48 publications

(44 citation statements)

References 52 publications

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“…For surface winds, we rely on ERA‐I and on the blended analysis of Desbiolles et al . [] that is available on a 1/4° grid, but only during 1992–2012.…”

Section: Data Usedmentioning

confidence: 99%

ENSO impact on surface radiative fluxes as observed from space

et al. 2017

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We investigate the impact of El Niño‐Southern Oscillation (ENSO) on surface radiative fluxes over the tropical Pacific using satellite observations and fluxes derived from selected atmospheric reanalyses. Agreement between the two in this region is important because reanalysis information is frequently used to assess surface energy budget sensitivity to ENSO. We found that during the traditional ENSO, the maximum variance of anomalous incoming solar radiation is located just west of the dateline and coincides with the area of the largest anomalous SST gradient. It can reach up to 60 W/m2 and lags behind the Niño3 index by about a month, suggesting a response to anomalous SST gradient. The magnitude of longwave anomaly is only half that large and varies in phase with the SST anomaly. Similar anomalies were derived from outputs: from the European Centre for Medium‐Weather Forecasts Reanalysis Interim (ERA‐I), from the Modern Era Retrospective Analysis version 2 (MERRA‐2), from the NCEP/NCAR Reanalysis 1 (R1), and from the Japanese JRA55 reanalysis. Among the four reanalyses used, results from ERA‐I are the closest to observations. We have also investigated the surface wind divergence/convergence and found that the main factor limiting eastward excursions of convection is the surface wind convergence. Due to the wind divergence pattern normally present over the eastern cold tongue, anomalous convection extends into the eastern equatorial Pacific only during the strongest warm events. Our analysis also considers the El Niño Modoki events, for which the radiation flux patterns are shifted westward following the SST pattern.

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“…For surface winds, we rely on ERA‐I and on the blended analysis of Desbiolles et al . [] that is available on a 1/4° grid, but only during 1992–2012.…”

Section: Data Usedmentioning

confidence: 99%

ENSO impact on surface radiative fluxes as observed from space

et al. 2017

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“…Resolving mesoscale eddies in oceanic models is required to quantitatively reproduce key features of the ocean circulation such as the Western Boundary Currents (Chassignet & Marshall, 2013;McWilliams, 2008), the Southern Ocean overturning (e.g., Downes et al, 2018;Hallberg & Gnanadesikan, 2006), and the total heat transport and biogeochemical variability (Colas et al, 2012;Dong et al, 2014;Gruber et al, 2011;McGillicuddy et al, 2007;Renault, Deutsch, McWilliams, et al, 2016). Meanwhile, satellite sensors such as scatterometers (e.g., QuikSCAT) have been used to better understand mesoscale air-sea interactions and to demonstrate their global ubiquity and effects on 10-m wind and surface stress (Chelton et al, 2001(Chelton et al, , 2004(Chelton et al, , 2007Chelton & Xie, 2010;Cornillon & Park, 2001;Desbiolles et al, 2017;Gaube et al, 2015;Kelly et al, 2001;Renault, McWilliams, & Masson, 2017;O'Neill et al, 2010O'Neill et al, , 2012. They also motivated model developments and numerical studies that aim to understand the air-sea interaction effects in both the atmosphere and the ocean (Desbiolles et al, 2016;Hogg et al, 2009;Minobe et al, 2008;Oerder et al, 2016Oerder et al, , 2018Renault, Molemaker, Gula, et al, 2016;Seo et al, 2016Seo et al, , 2019Seo, 2017).…”

Section: Introductionmentioning

confidence: 99%

Recipes for How to Force Oceanic Model Dynamics

Renault

Masson

Arsouze

et al. 2020

J Adv Model Earth Syst

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The current feedback to the atmosphere (CFB) contributes to the oceanic circulation by damping eddies. In an ocean‐atmosphere coupled model, CFB can be correctly accounted for by using the wind relative to the oceanic current. However, its implementation in a forced oceanic model is less straightforward as CFB also enhances the 10‐m wind. Wind products based on observations have seen real currents that will not necessarily correspond to model currents, whereas meteorological reanalyses often neglect surface currents or use surface currents that, again, will differ from the surface currents of the forced oceanic simulation. In this study, we use a set of quasi‐global oceanic simulations, coupled or not with the atmosphere, to (i) quantify the error associated with the different existing strategies of forcing an oceanic model, (ii) test different parameterizations of the CFB, and (iii) propose the best strategy to account for CFB in forced oceanic simulation. We show that scatterometer wind or stress are not suitable to properly represent the CFB in forced oceanic simulation. We furthermore demonstrate that a parameterization of CFB based on a wind‐predicted coupling coefficient between the surface current and the stress allows us to reproduce the main characteristics of a coupled simulation. Such a parameterization can be used with any forcing set, including future coupled reanalyses, assuming that the associated oceanic surface currents are known. A further assessment of the thermal feedback of the surface wind in response to oceanic surface temperature gradients shows a weak forcing effect on oceanic currents.

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“…However, when analyzing raw data, differences among the missions calibrations introduce bias in the wind stress tendency [38]. To solve this issue, wind data from sparse scatterometer fields (ERS, QuikSCAT, and ASCAT) have been processed by the IFREMER and compared to other data sources, such as radiometer data (SSM/I) and atmospheric wind reanalyses (ERA-Interim), to produce a new long time wind product described by Desbiolles et al [39]. This dataset provides 6 h wind stress maps at 1/4 • spatial resolution over the 2003-2016 period.…”

Section: Observational Datasetsmentioning

confidence: 99%

“…The imprint of CTWs is strong in the Northern HCS, but off Central Chile (30)(31)(32)(33)(34)(35)(36)(37)(38)(39)(40) • S) their amplitude is largely attenuated so that the SST can be inferred from a one-dimensional model forced by the local wind stress and solar heating [24]. The region off Central-South Chile (35)(36)(37)(38)(39)(40) • S) is characterized by a strong seasonality in the coastal wind stress and the wind stress curl, with upwelling-favorable wind conditions from September to April (e.g., [13,31]). The upwelling-induced coastal cold tongue is present from November to May, suggesting a lag in the seasonal response of the SST to the wind conditions [13].…”

Section: Introductionmentioning

confidence: 99%

Coastal Upwelling Front Detection off Central Chile (36.5–37°S) and Spatio-Temporal Variability of Frontal Characteristics

et al. 2018

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Abstract:In Eastern Boundary Upwelling Systems, cold coastal waters are separated from offshore by a strong cross-shore Sea Surface Temperature (SST) gradient zone. This upwelling front plays a major role for the coastal ecosystem. This paper proposes a method to automatically identify the front and define its main characteristics (position, width, and intensity) from high resolution data. The spatio-temporal variability of the front characteristics is then analyzed in a region off Central Chile (37 • S), from 2003 to 2016. The front is defined on daily 1 km-resolution SST maps by isotherm T 0 with T 0 computed from mean SST with respect to the distance from the coast. The probability of detecting a front, as well as the front width and intensity are driven by coastal wind conditions and increased over the 2007-2016 period compared to the 2003-2006 period. The front position, highly variable, is related to the coastal jet configuration and does not depend on the atmospheric forcing. This study shows an increase by 14% in the probability of detecting a front and also an intensification by 17% of the cross-front SST difference over the last 14 years. No trend was found in the front position.

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Two decades [1992–2012] of surface wind analyses based on satellite scatterometer observations

Cited by 48 publications

References 52 publications

ENSO impact on surface radiative fluxes as observed from space

ENSO impact on surface radiative fluxes as observed from space

Recipes for How to Force Oceanic Model Dynamics

Coastal Upwelling Front Detection off Central Chile (36.5–37°S) and Spatio-Temporal Variability of Frontal Characteristics

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