Sensitivity Studies of the Red Sea Eddies Using Adjoint Method

et al. 2020

Preprint

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The Ensemble Adjustment Kalman Filter (EAKF) of the Data Assimilation Research Testbed (DART) is implemented to assimilate observations of satellite sea surface temperature, altimeter sea surface height and in situ ocean temperature and salinity profiles into an eddyresolving 4 km-Massachusetts Institute of Technology general circulation model (MITgcm) of the Red Sea. We investigate the impact of three different ensemble generation strategies (1) Iexpuses ensemble of ocean states to initialize the model on 1 st January, 2011 and inflates filter error covariance by 10%, (2) IAexpadds ensemble of atmospheric forcing to Iexp, and(3) IAPexpadds perturbed model physics to IAexp. The assimilation experiments are run for one year, starting from the same initial ensemble and assimilating data every three days.Results demonstrate that the Iexp mainly improved the model outputs with respect to assimilation-free MITgcm run in the first few months, before showing signs of dynamical imbalances in the ocean estimates, particularly in the data-sparse subsurface layers. The IAexp yielded substantial improvements throughout the assimilation period with almost no signs of imbalances, including the subsurface layers. It further well preserved the model mesoscale features resulting in an improved forecasts for eddies, both in terms of intensity and location.Perturbing model physics in IAPexp slightly improved the forecast statistics and also the placement of basin-scale eddies. Increasing hydrographic coverage further improved the results of IAPexp compared to IAexp in the subsurface layers. Switching off multiplicative inflation in IAexp and IAPexp leads to further improvements, especially in the subsurface layers.

Section: Assimilated Observationsmentioning

confidence: 99%

Section: Impact Of Ensemble Atmospheric Forcingmentioning

confidence: 99%

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Impact of Atmospheric and Model Physics Perturbations On a High-Resolution Ensemble Data Assimilation System of the Red Sea

Sanikommu

Toye

et al. 2020

Preprint

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“…The model is forced by surface wind, air temperature, specific humidity, precipitation, and downward shortwave and longwave radiation of a 10-km Weather Research Forecast product (Viswanadhapalli et al, 2017) downscaled from ERA-Interim products of the European Centre for Medium-Range Weather Forecasts (Dee et al, 2011). In addition, the model outputs were validated against different observations and have been used in various studies, to name a few, the eddy energy budget , the adjoint sensitivity analysis of eddies (Zhan et al, 2018), and phytoplankton phenology in the southern (Dreano et al, 2016) and northern Red Sea (Gittings et al, 2018). This model is developed as an updated version of the one implemented by and Yao, Hoteit, Pratt, Bower, Zhai, et al (2014) to investigate the general and overturning circulation in the Red Sea.…”

Section: The Modelmentioning

confidence: 99%

“…These have been captured in various independent observations, including remotely sensed sea surface height (SSH) data (Bower & Farrar, 2015;Raitsos et al, 2017;Zhan et al, 2014), sea surface temperature (SST) data (Papadopoulos et al, 2015), chlorophyll-a data (Raitsos et al, 2013), synthetic aperture radar imagery (Karimova & Gade, 2014), and in situ observations (Sofianos & Johns, 2007;Zarokanellos et al, 2017;Zhai & Bower, 2013). Advances in high-performance computing resources now enable conducting high-resolution eddy-resolving numerical simulation of the Red Sea circulation with sufficient spatial and temporal resolution to investigate the three-dimensional characteristics of the Red Sea eddies (Zhan et al, , 2018. Nevertheless, the observations are sporadic and sparse in space and time.…”

Section: Introductionmentioning

confidence: 99%

Three‐Dimensional Signature of the Red Sea Eddies and Eddy‐Induced Transport

Geophysical Research Letters

Krokos

Guo

et al. 2019

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Mesoscale eddies are a dominant feature of the Red Sea circulation, yet their three‐dimensional characteristics remain largely unexplored. This hinders our understanding about eddy‐induced transport in the basin. This study analyzes 14‐year outputs from a high‐resolution eddy‐resolving model to investigate the three‐dimensional signature of the Red Sea eddies, their contribution to the air‐sea flux, and the eddy‐induced transport of heat and salt. Eddies are mostly active and energetic in the central and northern Red Sea. Their variability explains ∼8% of the total variance in the surface heat flux and, particularly, ∼39% in the salt flux. The asymmetric eddy structure and meridional gradient drive significant transport of heat and salt across the basin. A negative feedback mechanism is identified that relates the eddy intensity and the meridional steepness of the mixed layer depth in the basin.

Physical forcing of phytoplankton dynamics in the Al‐Wajh lagoon (Red Sea)

Limnol Oceanogr Letters

Krokos

Gittings

et al. 2022

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Based on contemporary data including remote sensing observations and high-resolution outputs of numerical simulations, we show that the seasonal phytoplankton bloom occurs during a different season within the Al-Wajh lagoon (August-September) in comparison to the adjacent open sea (January-February). We provide evidence that attributes these discrepancies to hydrodynamic conditions that determine nutrient availability. The surrounding reef barriers allow the lagoon water to acquire distinct characteristics compared to the open sea, and the lagoonal dynamics are primarily dominated by the interaction between the open ocean and lagoonal waters. The proposed mechanism may offer new insights into understanding the biophysical dynamics of non-estuarine coastal lagoons in other tropical regions of the global oceans.