Use of WorldView-2 Along-Track Stereo Imagery to Probe a Baltic Sea Algal Spiral

Marmorino, G. O.; Chen, Wei

doi:10.3390/rs11070865

Cited by 10 publications

(8 citation statements)

References 23 publications

(39 reference statements)

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“…In analogy to dense filaments (McWilliams et al, 2009;McWilliams, 2017), the secondary circulation is an overturning cell with intense downwelling in the eddy center and weak upwelling at the periphery. Besides the ability to accumulate ice (Manucharyan and Thompson, 2017), the convergent near-surface flow may concentrate any other buoyant flotsam in submesoscale cyclones, such as plastic debris (van Sebille et al, 2020;Barboza et al, 2019;Turner et al, 2019), oil (D'Asaro et al, 2018, macroalgae (Zhong et al, 2012), buoyant plankton (Hernández-Hernández et al, 2020), or cyanobacteria (Marmorino and Chen, 2019).…”

Section: Discussionmentioning

confidence: 99%

Properties and evolution of a submesoscale cyclonic spiral

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Baschek

2021

Preprint

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Abstract. The evolution of a submesoscale cyclonic spiral of 1 km in diameter is simulated with ROMS (Regional Ocean Modeling System) using 33.3 m horizontal resolution in a triple-nested configuration. The generation of the spiral starts from a dense filament that is rolled into a vortex and detaches from the filament. During spin-up, extreme values are attained by various quantities, that are organized in single-arm and multi-arm spirals. The spin-down starts when the cyclone separates from the filament. At the same time, the horizontal speed develops a dipole-like pattern and isotachs form closed contours around the vortex center. The amplitudes of most quantities decrease significantly, but the instantaneous vertical velocity w exhibits high-frequency oscillations and more pronounced extremes than during spin-up. The oscillations are due to vortex Rossby waves (VRWs), that circle the eddy counterclockwise and generate multi-arm spirals with alternating signs by means of azimuthal vorticity advection. Experiments with virtual surface drifters and isopycnal floats indicate downwelling everywhere near the surface. The downwelling is most intense in the center of the spiral at all depth levels, leading to a radial outflow in the thermocline and weak upwelling at the periphery. This overturning circulation is driven by convergent near-surface flow and associated subduction of isopycnals. While the downwelling in the center may support the export of particulate organic carbon from the mixed layer into the main thermocline, the upwelling at the periphery effectuates an upward isopycnal transport of nutrients, enhancing the growth of phytoplankton in the euphotic zone.

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Section: Discussionmentioning

confidence: 99%

Properties and evolution of a submesoscale cyclonic spiral

Onken

Baschek

2021

Preprint

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“…To estimate the velocity field from a pair of sequential SAR images, we implement the following procedure: (i) image calibration for every image in the pair; (ii) selection of overlapping image fragments, their normalization and filtering; and (iii) calculation of horizontal velocity field for image fragments using one of the methods for velocity estimation from image sequences (e.g., Emery et al, 1986;Chen, 2011;Marmorino and Chen, 2019). The Sentinel-1 images are calibrated to obtain the normalized radar cross-section units.…”

Section: Methodsmentioning

confidence: 99%

“…This issue is addressed during the normalization step but might be difficult to overcome for very thin ice whose backscatter is very sensitive to the described changes in the viewing geometry and near-surface winds. For demonstration, here we use the maximum cross-correlation method (MCC) (Emery et al, 1986;Qazi et al, 2014) to retrieve the surface velocity vectors, but we acknowledge that more elaborated velocimetry methods can also be used for this purpose (see e.g., Chen, 2011;Marmorino and Chen, 2019). The preliminary analysis of SAR data from various dates in summer 2017 suggests that MCC works rather effectively for typical sea ice concentrations encountered along the ice edge and in the marginal ice zone, provided the movement of ice floes is apparent in the sequential SAR images.…”

Section: Methodsmentioning

confidence: 99%

Brief Communication: Mesoscale and submesoscale dynamics in the marginal ice zone from sequential synthetic aperture radar observations

2020

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Abstract. New possibilities for horizontal current retrieval in marginal ice zones (MIZs) from sequential Sentinel-1 synthetic aperture radar (SAR) images are demonstrated. Daily overlapping SAR acquisitions within 70–85∘ S/N at time intervals < 1 h enable estimation of high-resolution velocity fields, revealing MIZ dynamics down to submesoscales. An example taken from the Fram Strait MIZ reveals energetic eddies and filaments with Rossby numbers reaching O(1) magnitudes. The SAR-derived velocity estimations at such high spatial resolution can be critical for monitoring the evolving MIZ dynamics and model validation of submesoscale processes in polar oceans.

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“…The procedure of velocity estimation from sequential SAR images has several main steps: i) image calibration for every image in the pair, ii) selection of overlapping image fragments, their normalization and filtering, iii) calculation of horizontal velocity field for image fragments using one of the methods for velocity estimation from image sequences (e.g. Emery et al, 1986;Chen, 2011;Marmorino and Chen, 2019). At first, S-1 images were calibrated to obtain normalized radar cross-section units.…”

Section: Methodsmentioning

confidence: 99%

“…We also 85 acknowledge that more elaborated alternative methods can be used for this purpose (see e.g. Chen, 2011;Marmorino and Chen, 2019). Given the spatial resolution of the SAR images of 88×87 m in range and azimuth directions, and the time lag between sequential images equal to 48 minutes, the velocity detection threshold in this case would be 0.03 m s -1 , similar to (Marmorino and Chen, 2019).…”

Section: Methodsmentioning

confidence: 99%