Aquarius geophysical model function and combined active passive algorithm for ocean surface salinity and wind retrieval

Yueh, Simon; Tang, Wenqing; Fore, Alexander; Hayashi, Atsushi; Song, Yuhe; Lagerloef, Gary

doi:10.1002/2014jc009939

Cited by 66 publications

(56 citation statements)

References 37 publications

(40 reference statements)

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“…In contrast, the L-band amplitude at low and moderate wind speeds (4 and 8 m/s) along upwind (0°) or downwind (180°) directions is less than one along crosswind (90° or 270°) directions, which signifies the negative upwind-crosswind asymmetry. It is consistent with the directional feature observed by Yueh et al [17], Zhou et al [18] and Isoguchi et al [28] and. In addition, the difference of the directional spreading function between L, C and Ku band decreases with the increase of wind speed.…”

Section: Derivation and Calculation Of Directional Spreading Functionsupporting

confidence: 92%

Directional Spreading Function of the Gravity-Capillary Wave Spectrum Derived from Radar Observations

Zhou

Chong

et al. 2017

Remote Sensing

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Directional spreading function of the gravity-capillary wave spectrum can provide the high-wavenumber wave energy distribution among different directions on the sea surface. The existing directional spreading functions have been mainly developed for the low-wavenumber gravity wave with buoy data. In this paper, we use radar observations to derive the directional spreading function of the gravity-capillary wave spectrum, which is expressed as the second-order Fourier series expansion. So far the standard form of the second-order harmonic coefficient has not been proposed to correctly unify the gravity and gravity-capillary wave. Our strategy is to introduce a correcting term to replace the inaccurate gravity-capillary spectral component in Elfouhaily's directional spreading function. The second-order harmonic coefficient at L, C and Ku band calculated by the radar observation is used to fit the correcting term to obtain one at the full gravity-capillary wave region. According to our proposed the directional spreading function, there is a spectral region between the gravity and gravity-capillary range where it signifies the negative upwind-crosswind asymmetry at low and moderate speed range. And this is not reflected by the previous models, but has been confirmed by radar observations. The Root Mean Square Difference (RMSD) of the proposed second-order harmonic coefficient versus the radar-observed one at L, C band Ku band is 0.0438, 0.0263 and 0.0382, respectively. The overall bias and RMSD are −0.0029 and 0.0433 for the whole second-order harmonic coefficient range, respectively. The result verifies the accuracy of the proposed directional spreading function at L, C band Ku band.

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Section: Derivation and Calculation Of Directional Spreading Functionsupporting

confidence: 92%

Directional Spreading Function of the Gravity-Capillary Wave Spectrum Derived from Radar Observations

Zhou

Chong

et al. 2017

Remote Sensing

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“…8), where the two Aquarius e w are different at WS above 10 m s −1 and the SMOS e w is close to the one of Yueh et al (2014). However, they disagree with SMOS models derived using ECMWF wind speeds for WS above 17 m s −1 .…”

Section: Resultsmentioning

confidence: 75%

“…To derive e w , many in-situ and airborne efforts using various instruments and observation techniques have been performed, e.g., the experiment made from a tower (Hollinger, 1971), the Wind and Salinity Experiments (WISE) Etcheto et al, 2004), the airborne Passive-Active L-band Sensor (PALS) campaign (Yueh, Dinardo, Fore, & Li, 2010) and the Combined Airborne Radio instruments for Ocean and Land Studies (CAROLS) campaign (Martin et al, 2012;Martin, Boutin, Hauser, & Dinnat, 2014). Recently, new empirical roughness models were proposed using space-borne measurements such as those from the Soil Moisture and Ocean Salinity (SMOS) mission (Guimbard et al, 2012;Reul & Tenerelli, personal communication, 2012) and the Aquarius mission (Yueh et al, 2013;Yueh et al, 2014;Meissner, Wentz, & Ricciardulli, 2014). A semi-physical model was also proposed by adjusting the Durden-Vesecky (1985) wave spectrum and the Monahan and O'Muircheartaigh (1986) foam coverage model using SMOS data (Yin, Boutin, Martin, & Spurgeon, 2012a).…”

Section: Introductionmentioning

confidence: 99%

Roughness and foam signature on SMOS-MIRAS brightness temperatures: A semi-theoretical approach

Yin

Boutin

Dinnat

et al. 2016

Remote Sensing of Environment

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“…More information about the algorithm and the data validation can be found in Yueh et al . [] and Tang et al . [].…”

Section: Methodsmentioning

confidence: 99%

Pacific Ocean surface freshwater variability underneath the double ITCZ as seen by satellite sea surface salinity retrievals

Martins

Stammer

2015

JGR Oceans

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The salinity budget of the upper tropical Pacific Ocean underneath the double Intertropical Convergence Zone (ITCZ) is studied using the Soil Moisture and Ocean Salinity (SMOS) and Aquarius surface salinity observations as well as in situ salinity measurements. In this shallow mixed layer region of the ocean, precipitation effects on the near‐surface salinity budget are large, typically leading to a band of fresh sea surface salinity (SSS) between March and June. The role of precipitation during the freshening period is documented here through a direct correlation between the SMOS SSS fields and the monthly accumulated precipitation. During the same period, the mixed layer salinity budget is impacted by advection, which, based on in situ observations, is found to be another important mechanism for the evolution of the near‐surface salinity as documented through a connection between the north equatorial eastern Pacific Fresh water pool and this south equatorial freshwater pattern in boreal spring. However, given the information at hand, the near‐surface salinity budget cannot be closed, suggesting that other processes are important too, such as nonlinear effects, mixing, and entrainment.

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Aquarius geophysical model function and combined active passive algorithm for ocean surface salinity and wind retrieval

Cited by 66 publications

References 37 publications

Directional Spreading Function of the Gravity-Capillary Wave Spectrum Derived from Radar Observations

Directional Spreading Function of the Gravity-Capillary Wave Spectrum Derived from Radar Observations

Roughness and foam signature on SMOS-MIRAS brightness temperatures: A semi-theoretical approach

Pacific Ocean surface freshwater variability underneath the double ITCZ as seen by satellite sea surface salinity retrievals

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