Characterising primary productivity measurements across a dynamic western boundary current region

AbstractA quality control (QC) procedure is developed to estimate monthly mean climatologies from the large Argo dataset (2005–12) over the North Pacific western boundary current region. In addition to the individual QC procedure, which checks for instrumental, transmission, and gross errors, the paper describes and shows the impact of climatological checks (collective QC) on the quality of both processed profiles and resultant climatological distributions. Objective analysis (OA) is applied progressively to produce the gridded climatological fields. The method uses horizontal regional climatological averages defined in five regime-oriented subregions in the Kuroshio area and the Japan Sea. Performing the QC procedure on specific coherent subregions produces improved profiling data and climatological fields because more details about the local hydrodynamics are taken into consideration. Nonrepresentative data and random noises are more effectively rejected by this method, which has value both in defining a climatological mean and identifying outlier data. Assessing with both profiling and coordinated datasets, the agreement is reasonably good (particularly for those areas with abundant observations), but the results (although already smoothed) can capture more detailed or mesoscale features for further regional studies. The method described has the potential to meet future challenges in processing accumulating Argo observations in the coming decades.

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Environmental drivers of abundance and residency of a large migratory shark, Carcharhinus leucas, inshore of a dynamic western boundary current

Marine Ecology Progress Series ◽

10.3354/meps13052 ◽

2019 ◽

Vol 622 ◽

pp. 121-137 ◽

Cited By ~ 6

Author(s):

KA Lee ◽

AF Smoothey ◽

RG Harcourt ◽

M Roughan ◽

PA Butcher ◽

...

Keyword(s):

Western Boundary Current ◽

Environmental Drivers ◽

Western Boundary ◽

Boundary Current ◽

Carcharhinus Leucas

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Frequency-Domain Analysis of the Energy Budget in an Idealized Coupled Ocean–Atmosphere Model

Journal of Climate ◽

10.1175/jcli-d-19-0118.1 ◽

2020 ◽

Vol 33 (2) ◽

pp. 707-726 ◽

Cited By ~ 1

Author(s):

Paige E. Martin ◽

Brian K. Arbic ◽

Andrew McC. Hogg ◽

Andrew E. Kiss ◽

James R. Munroe ◽

...

Keyword(s):

Frequency Domain ◽

Time Scales ◽

Energy Budget ◽

Western Boundary Current ◽

Spectral Energy ◽

Western Boundary ◽

Intrinsic Variability ◽

Boundary Current ◽

Ocean Atmosphere ◽

Atmosphere Model

AbstractClimate variability is investigated by identifying the energy sources and sinks in an idealized, coupled, ocean–atmosphere model, tuned to mimic the North Atlantic region. The spectral energy budget is calculated in the frequency domain to determine the processes that either deposit energy into or extract energy from each fluid, over time scales from one day up to 100 years. Nonlinear advection of kinetic energy is found to be the dominant source of low-frequency variability in both the ocean and the atmosphere, albeit in differing layers in each fluid. To understand the spatial patterns of the spectral energy budget, spatial maps of certain terms in the spectral energy budget are plotted, averaged over various frequency bands. These maps reveal three dynamically distinct regions: along the western boundary, the western boundary current separation, and the remainder of the domain. The western boundary current separation is found to be a preferred region to energize oceanic variability across a broad range of time scales (from monthly to decadal), while the western boundary itself acts as the dominant sink of energy in the domain at time scales longer than 50 days. This study paves the way for future work, using the same spectral methods, to address the question of forced versus intrinsic variability in a coupled climate system.

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Midlatitude–Equatorial Dynamics of a Grounded Deep Western Boundary Current. Part I: Midlatitude Flow and the Transition to the Equatorial Region

Journal of Physical Oceanography ◽

10.1175/jpo-d-14-0207.1 ◽

2015 ◽

Vol 45 (10) ◽

pp. 2457-2469 ◽

Cited By ~ 4

Author(s):

Gordon E. Swaters

Keyword(s):

Bottom Topography ◽

Zonal Flow ◽

Ocean Basin ◽

Equatorial Region ◽

Western Boundary Current ◽

Western Boundary ◽

Boundary Current ◽

Qualitative Properties ◽

Deep Western Boundary Current ◽

The Tropics

AbstractA comprehensive theoretical study of the nonlinear hemispheric-scale midlatitude and cross-equatorial steady-state dynamics of a grounded deep western boundary current is given. The domain considered is an idealized differentially rotating, meridionally aligned basin with zonally varying parabolic bottom topography so that the model ocean shallows on both the western and eastern sides of the basin. Away from the equator, the flow is governed by nonlinear planetary geostrophic dynamics on sloping topography in which the potential vorticity equation can be explicitly solved. As the flow enters the equatorial region, it speeds up and becomes increasingly nonlinear and passes through two distinguished inertial layers referred to as the “intermediate” and “inner” inertial equatorial boundary layers, respectively. The flow in the intermediate equatorial region is shown to accelerate and turn eastward, forming a narrow equatorial jet. The qualitative properties of the solution presented are consistent with the known dynamical characteristics of the deep western boundary currents as they flow from the midlatitudes into the tropics. The predominately zonal flow across the ocean basin in the inner equatorial region (and its exit from the equatorial region) is determined in Part II of this study.

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