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  • 1
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    Surface gravity wave effects on submesoscale currents in the open ocean
    American Meteorological Society ; 2021
    In:  Journal of Physical Oceanography ( 2021-09-09)
    Details
    In: Journal of Physical Oceanography, American Meteorological Society, ( 2021-09-09)
    Kurzfassung: A set of realistic coastal simulations in California allows for the exploration of surface gravity wave effects on currents (WEC) in an active submesoscale current regime. We use a new method that takes into account the full surface gravity wave spectrum and produces larger Stokes drift than the monochromatic peak-wave approximation. We investigate two high wave events lasting several days — one from a remotely generated swell and another associated with local wind-generated waves — and perform a systematic comparison between solutions with and without WEC at two submesoscale-resolving horizontal grid resolutions ( dx = 270 m and 100 m). WEC results in the enhancement of open-ocean surface density and velocity gradients when the averaged significant wave height H S is relatively large ( 〉 4.2m). For smaller waves, WEC is a minor effect overall. For the remote swell (strong waves and weak winds), WEC maintains submesoscale structures and accentuates the cyclonic vorticity and horizontal convergence skewness of submesoscale fronts and filaments. The vertical enstrophy ζ 2 budget in cyclonic regions ( ζ/f 〉 2) reveals enhanced vertical shear and enstrophy production via vortex tilting and stretching. Wind-forced waves also enhance surface gradients, up to the point where they generate a small-submesoscale roll-cell pattern with high vorticity and divergence that extends vertically through the entire mixed layer. The emergence of these roll-cells results in a buoyancy gradient sink near the surface that causes a modest reduction in the typically large submesoscale density gradients.
    Materialart: Online-Ressource
    ISSN: 0022-3670 , 1520-0485
    URL: Article
    DOI: 10.1175/JPO-D-20-0306.1
    Sprache: Unbekannt
    Verlag: American Meteorological Society
    Publikationsdatum: 2021
    ZDB Id: 2042184-9
    ZDB Id: 184162-2
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  • 2
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    Interactions Between Internal Tidal Bores and Submesoscale Currents on the Continental Shelf
    American Geophysical Union (AGU) ; 2023
    In:  Journal of Geophysical Research: Oceans Vol. 128, No. 2 ( 2023-02)
    Details
    In: Journal of Geophysical Research: Oceans, American Geophysical Union (AGU), Vol. 128, No. 2 ( 2023-02)
    Kurzfassung: A realistic simulation reveals interactions between internal tidal bores and submesoscale currents Submesoscale stratification and velocity gradients modulate bore shoaling Bores disrupt submesoscale secondary circulation
    Materialart: Online-Ressource
    ISSN: 2169-9275 , 2169-9291
    URL: Article
    DOI: 10.1029/2022JC018747
    Sprache: Englisch
    Verlag: American Geophysical Union (AGU)
    Publikationsdatum: 2023
    ZDB Id: 2016804-4
    ZDB Id: 161667-5
    ZDB Id: 3094219-6
    SSG: 16,13
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  • 3
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    Nearshore Lagrangian Connectivity: Submesoscale Influence and Resolution Sensitivity
    American Geophysical Union (AGU) ; 2019
    In:  Journal of Geophysical Research: Oceans Vol. 124, No. 7 ( 2019-07), p. 5180-5204
    Details
    In: Journal of Geophysical Research: Oceans, American Geophysical Union (AGU), Vol. 124, No. 7 ( 2019-07), p. 5180-5204
    Kurzfassung: Simulated nearshore connectivity is sensitive to horizontal resolution At resolutions less than 100 m, previously unresolved currents open up new transport pathways Nearshore submesoscale currents are responsible for early time downwelling and dispersal of material
    Materialart: Online-Ressource
    ISSN: 2169-9275 , 2169-9291
    URL: Article
    DOI: 10.1029/2019JC014943
    Sprache: Englisch
    Verlag: American Geophysical Union (AGU)
    Publikationsdatum: 2019
    ZDB Id: 2016804-4
    ZDB Id: 161667-5
    ZDB Id: 3094219-6
    SSG: 16,13
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  • 4
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    Data_Sheet_1.pdf
    Frontiers Media SA ; 2022
    In:  Frontiers in Marine Science Vol. 9 ( 2022-3-3)
    Details
    In: Frontiers in Marine Science, Frontiers Media SA, Vol. 9 ( 2022-3-3)
    Kurzfassung: Offshore aquaculture has the potential to expand the macroalgal industry. However, moving into deeper waters requires suspended structures that will present novel farm-environment interactions. Here, we present a computational modeling framework, the Macroalgal Cultivation Modeling System (MACMODS), to explore within-farm modifications to light, seawater flow, and nutrient fields across time and space scales relevant to macroalgae. A regional ocean model informs the site-specific setting, the Santa Barbara Channel in the Southern California Bight. A fine-scale hydrodynamic model predicts modified flows and turbulent mixing within the farm. A spatially resolved macroalgal growth model, parameterized for giant kelp, Macrocystis pyrifera , predicts kelp biomass. Key findings from model integration are that regional ocean conditions set overall farm performance, while fine-scale within-farm circulation and nutrient delivery are important to resolve variation in within-farm macroalgal performance. Therefore, we conclude that models resolving within-farm dynamics can provide benefit to farmers with insight on how farm design and regional ocean conditions interact to influence overall yield. Here, the presence of repeating longlines aligned with the mean current generate flow diversions around the farm as well as attached Langmuir circulations and increased turbulence intensity. These flow-induced phenomena lead to less biomass in the interior portion of the farm relative to the edges. We also find that there is an effluent “footprint” that extends as much as 20 km beyond the farm. In this regard, MACMODS can be used to not only evaluate farm design and cultivation practices that maximize yield but also explore interactions between the farm and ecosystem in order to minimize impacts.
    Materialart: Online-Ressource
    ISSN: 2296-7745
    URL: Article
    URL: Article
    DOI: 10.3389/fmars.2022.752951
    DOI: 10.3389/fmars.2022.752951.s001
    Sprache: Unbekannt
    Verlag: Frontiers Media SA
    Publikationsdatum: 2022
    ZDB Id: 2757748-X
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  • 5
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    Effects of Stratification on Shoaling Internal Tidal Bores
    American Meteorological Society ; 2021
    In:  Journal of Physical Oceanography ( 2021-08-19)
    Details
    In: Journal of Physical Oceanography, American Meteorological Society, ( 2021-08-19)
    Kurzfassung: Idealized simulations of a shoaling internal tide on a gently sloping, linear shelf provide a tool to investigate systematically the effects of stratification strength, vertical structure, and internal wave amplitude on internal tidal bores. Simulations that prescribe a range of uniform or variable stratifications and wave amplitudes demonstrate a variety of internal tidal bores characterized by shoreward propagating horizontal density fronts with associated overturning circulations. Qualitatively, we observe three classes of solution: 1) bores, 2) bores with trailing wave trains, and 3) no bores. Very strong stratification (small wave) or very weak stratification (large wave) inhibits bore formation. Bores exist in an intermediate zone of stratification strength and wave amplitude. Within this intermediate zone, wave trains can trail bores if the stratification is relatively weak or wave amplitude large. We observe three types of bore that arise dependent on the vertical structure of stratification and wave amplitude: 1) a ‘backward’ downwelling front (near uniform stratification, small to intermediate waves), 2) a ‘forward’ upwelling front (strong pycnocline, small to large waves), and 3) a ‘double’ bore with leading up and trailing downwelling front (intermediate pycnocline, intermediate to large waves). Visualization of local flow structures explores the evolution of each of these bore-types. A frontogenetic diagnostic framework elucidates the previously undiscussed, yet, universal role of vertical straining of a stratified fluid that initiates formation of bores. Bores with wave trains exhibit strong non-hydrostatic dynamics. The results of this study suggest that mid-to-outer shelf measurements of stratification and cross-shore flow can serve as proxies to indicate the class of bore further inshore.
    Materialart: Online-Ressource
    ISSN: 0022-3670 , 1520-0485
    URL: Article
    DOI: 10.1175/JPO-D-21-0107.1
    Sprache: Unbekannt
    Verlag: American Meteorological Society
    Publikationsdatum: 2021
    ZDB Id: 2042184-9
    ZDB Id: 184162-2
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  • 6
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    Diurnal Evolution of Submesoscale Front and Filament Circulations
    American Meteorological Society ; 2018
    In:  Journal of Physical Oceanography Vol. 48, No. 10 ( 2018-10), p. 2343-2361
    Details
    In: Journal of Physical Oceanography, American Meteorological Society, Vol. 48, No. 10 ( 2018-10), p. 2343-2361
    Kurzfassung: The local circulation of submesoscale fronts and filaments can be partly understood through a horizontal momentum balance of Coriolis, a horizontal pressure gradient, and vertical diffusivity in a turbulent boundary layer, known as the turbulent thermal wind balance (TTW or T 2 W). T 2 W often reproduces the instantaneous relative vorticity and divergence of submesoscale circulations in open-ocean and shelf settings. However, a diurnal cycle in submesoscale vorticity and divergence is characterized by a non-T 2 W phasing: a maximum in divergence magnitude lags the maximum in vertical diffusivity (with vorticity lagging divergence). Here, an idealized model is used to solve the transient turbulent thermal wind (T 3 W) equations and to investigate the diurnal evolution of front and filament circulation in a 2D plane. Relative to a steady-state circulation, transient evolution can cause both instantaneous strengthening and a weaker diurnal average of the secondary circulation. The primary mechanisms controlling the diurnal variability exist in a 1D Ekman layer that imprints onto the 2D circulation. In midlatitudes, acceleration during separate phases of the diurnal cycle (from night to day and from day to night) is dominated by distinct inertial oscillation and vertically diffusive mechanisms, respectively. However, the manifestation of these dual accelerations is sensitive to latitude, boundary layer depth, and the strength of the forcing. A simple 1D model predicts the diurnal phasing of submesoscale divergence and vorticity in realistic primitive equation simulations of the southwestern Pacific and coastal California.
    Materialart: Online-Ressource
    ISSN: 0022-3670 , 1520-0485
    URL: Article
    URL: Article
    DOI: 10.1175/JPO-D-18-0143.1
    DOI: 10.1175/JPO-D-18-0143.s1
    Sprache: Unbekannt
    Verlag: American Meteorological Society
    Publikationsdatum: 2018
    ZDB Id: 2042184-9
    ZDB Id: 184162-2
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  • 7
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    Diurnal Cycling of Submesoscale Dynamics: Lagrangian Implications in Drifter Observations and Model Simulations of the Northern Gulf of Mexico
    American Meteorological Society ; 2020
    In:  Journal of Physical Oceanography Vol. 50, No. 6 ( 2020-06), p. 1605-1623
    Details
    In: Journal of Physical Oceanography, American Meteorological Society, Vol. 50, No. 6 ( 2020-06), p. 1605-1623
    Kurzfassung: The diurnal cycling of submesoscale circulations in vorticity, divergence, and strain is investigated using drifter data collected as part of the Lagrangian Submesoscale Experiment (LASER) experiment, which took place in the northern Gulf of Mexico during winter 2016, and ROMS simulations at different resolutions and degree of realism. The first observational evidence of a submesoscale diurnal cycle is presented. The cycling is detected in the LASER data during periods of weak winds, whereas the signal is obscured during strong wind events. Results from ROMS in the most realistic setup and in sensitivity runs with idealized wind patterns demonstrate that wind bursts disrupt the submesoscale diurnal cycle, independently of the time of day at which they happen. The observed and simulated submesoscale diurnal cycle supports the existence of a shift of approximately 1–3 h between the occurrence of divergence and vorticity maxima, broadly in agreement with theoretical predictions. The amplitude of the modeled signal, on the other hand, always underestimates the observed one, suggesting that even a horizontal resolution of 500 m is insufficient to capture the strength of the observed variability in submesoscale circulations. The paper also presents an evaluation of how well the diurnal cycle can be detected as function of the number of Lagrangian particles. If more than 2000 particle triplets are considered, the diurnal cycle is well captured, but for a number of triplets comparable to that of the LASER analysis, the reconstructed diurnal cycling displays high levels of noise both in the model and in the observations.
    Materialart: Online-Ressource
    ISSN: 0022-3670 , 1520-0485
    URL: Article
    URL: Article
    DOI: 10.1175/JPO-D-19-0241.1
    DOI: 10.1175/JPO-D-19-0241.s1
    Sprache: Unbekannt
    Verlag: American Meteorological Society
    Publikationsdatum: 2020
    ZDB Id: 2042184-9
    ZDB Id: 184162-2
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  • 8
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    Submesoscale Coherent Structures on the Continental Shelf
    American Meteorological Society ; 2017
    In:  Journal of Physical Oceanography Vol. 47, No. 12 ( 2017-12), p. 2949-2976
    Details
    In: Journal of Physical Oceanography, American Meteorological Society, Vol. 47, No. 12 ( 2017-12), p. 2949-2976
    Kurzfassung: Discovery and analysis of submesoscale variability O (0.3–30) km on the continental shelf is made possible by a high-resolution (Δ x = 75 m) Regional Oceanic Modeling System (ROMS) simulation of the Southern California Bight (SCB). This variability is manifest in ubiquitous yet ephemeral coherent structures: fronts, filaments, and vortices. Similar to their open-ocean counterparts, fronts and filaments on the shelf are identified by their strong vertical velocity, surface convergence, cyclonic vorticity, and horizontal density gradient. Life cycles of these features typically last 3–5 days, with the formation dominated by a horizontal advective tendency that increases density and velocity gradients (i.e., frontogenesis). The shape of the coastline and depth of the water column both influence the abundance and spatial orientation of shallow-water fronts and filaments. Closer to shore, fronts and filaments often align themselves parallel to isobaths, and headlands often act as sites of intense vorticity generation through bottom stress. A quasi-steady, approximate momentum balance among rotation, pressure gradient, and vertical mixing—known as turbulent thermal wind (TTW)—often is valid in the strong secondary circulations local to fronts and filaments. However, front and filament circulations subject to strong diurnal variation in surface heating and vertical mixing are inconsistent with steady-state TTW balance. The secondary circulations can induce ephemeral material trapping and substantial vertical heat fluxes on the shelf.
    Materialart: Online-Ressource
    ISSN: 0022-3670 , 1520-0485
    URL: Article
    URL: Article
    DOI: 10.1175/JPO-D-16-0270.1
    DOI: 10.1175/JPO-D-16-0270.s1
    Sprache: Unbekannt
    Verlag: American Meteorological Society
    Publikationsdatum: 2017
    ZDB Id: 2042184-9
    ZDB Id: 184162-2
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  • 9
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    Langmuir Circulations Transfer Kinetic Energy from Submesoscales and Larger Scales to Dissipative Scales
    American Meteorological Society ; 2023
    In:  Journal of Physical Oceanography Vol. 53, No. 1 ( 2023-01), p. 253-268
    Details
    In: Journal of Physical Oceanography, American Meteorological Society, Vol. 53, No. 1 ( 2023-01), p. 253-268
    Kurzfassung: Surface gravity wave effects on currents (WEC) cause the emergence of Langmuir cells (LCs) in a suite of high horizontal resolution (Δ x = 30 m), realistic oceanic simulations in the open ocean of central California. During large wave events, LCs develop widely but inhomogeneously, with larger vertical velocities in a deeper mixed layer. They interact with extant submesoscale currents. A 550-m horizontal spatial filter separates the signals of LCs and of submesoscale and larger-scale currents. The LCs have a strong velocity variance with small density gradient variance, while submesoscale currents are large in both. Using coarse graining, we show that WEC induces a forward cascade of kinetic energy in the upper ocean up to at least a 5-km scale. This is due to strong positive vertical Reynolds stress (in both the Eulerian and the Stokes drift energy production terms) at all resolved scales in the WEC solutions, associated with large vertical velocities. The spatial filter elucidates the role of LCs in generating the shear production on the vertical scale of Stokes drift (10 m), while submesoscale currents affect both the horizontal and vertical energy fluxes throughout the mixed layer (50–80 m). There is a slightly weaker forward cascade associated with nonhydrostatic LCs (by 13% in average) than in the hydrostatic case, but overall the simulation differences are small. A vertical mixing scheme K -profile parameterization (KPP) partially augmented by Langmuir turbulence yields wider LCs, which can lead to lower surface velocity gradients compared to solutions using the standard KPP scheme.
    Materialart: Online-Ressource
    ISSN: 0022-3670 , 1520-0485
    URL: Article
    DOI: 10.1175/JPO-D-22-0126.1
    Sprache: Unbekannt
    Verlag: American Meteorological Society
    Publikationsdatum: 2023
    ZDB Id: 2042184-9
    ZDB Id: 184162-2
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