Buoyancy-Driven Coastal Currents off Oregon during Fall and Winter

Mazzini, Piero L. F.; Barth, John A.; Shearman, R. Kipp; Erofeev, A.

doi:10.1175/jpo-d-14-0012.1

Cited by 49 publications

(36 citation statements)

References 55 publications

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“…Cross‐shore glider transects recorded many appearances of the CRP through the 7 years of study, however, here we only present results from the glider trajectories that are concordant with clear MODIS nLw(555) fields identifying both the presence and absence of the CR plume. The MODIS imagery also revealed that some events with low‐salinity water were consistent with the signal from the small local rivers of central Oregon [ Mazzini et al ., ] under upwelling conditions and mostly during early spring. Thus, glider data suggesting the presence of the CR plume but not supported by a clear MODIS image showing the presence of the CR plume were discarded in order to avoid the inclusion of glider data under the influence of these small rivers.…”

Section: Resultsmentioning

confidence: 98%

Optics of the offshore Columbia River plume from glider observations and satellite imagery

et al. 2016

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The Columbia River (CR) is the largest source of freshwater along the U.S. Pacific coast. The resultant plume is often transported southward and offshore forming a large buoyant feature off Oregon and northern California in spring‐summer—the offshore CR plume. Observations from autonomous underwater gliders and Moderate Resolution Imaging Spectroradiometer (MODIS) satellite imagery are used to characterize the optics of the offshore CR plume off Newport, Oregon. Vertical sections, under contrasting river flow conditions, reveal a low‐salinity and warm surface layer of ∼20–25 m (fresher in spring and warmer in summer), high Colored Dissolved Organic Matter (CDOM) concentration, and backscatter, and associated with the base of the plume high chlorophyll fluorescence. Plume characteristics vary in the offshore direction as the warm and fresh surface layer thickens progressively to an average 30–40 m of depth 270–310 km offshore; CDOM, backscatter, and chlorophyll fluorescence decrease in the upper 20 m and increase at subsurface levels (30–50 m depth). MODIS normalized water‐leaving radiance (nLw(λ)) spectra for CR plume cases show enhanced water‐leaving radiance at green bands (as compared to no‐CR plume cases) up to ∼154 km from shore. Farther offshore, the spectral shapes for both cases are very similar, and consequently, a contrasting color signature of low‐salinity plume water is practically imperceptible from ocean color remote sensing. Empirical algorithms based on multivariate regression analyses of nLw(λ) plus SST data produce more accurate results detecting offshore plume waters than previous studies using single visible bands (e.g., adg(412) or nLw(555)).

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Section: Resultsmentioning

confidence: 98%

Optics of the offshore Columbia River plume from glider observations and satellite imagery

et al. 2016

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“…Deploying gear in the ocean involves some risk, as described for gliders by Brito et al (2014), whose view is based on many users new to gliders and is therefore rather bleak. My opinion is that more experienced glider operators have better performance, as must be the case for the glider programs that have been gathering data continuously for several years , Perry et al 2008, Todd et al 2011a, Pierce et al 2012, Pelland et al 2013, Mazzini et al 2014, Johnston & Rudnick 2015. The optimistic view is 10 August 2015 14:1 that ocean scientists willing to make an investment can approach the performance of experienced glider operators.…”

Section: Discussionmentioning

confidence: 99%

“…Davis (2010) used gliders equipped with ADCPs to show that the return flow is just beneath the surface wind-forced Ekman layer, implying that the heat flux is less than what would be expected if the return flow extended to the bottom. Sustained observations off Oregon have elucidated the buoyancy-driven currents associated with river discharge (Mazzini et al 2014). Timmermans & Winsor (2013) used two glider missions in the Chukchi Sea to examine the submesoscale horizontal structure in the surface layer.…”

Section: The Mesoscale and Submesoscalementioning

confidence: 99%

Ocean Research Enabled by Underwater Gliders

Rudnick

2016

Annu. Rev. Mar. Sci.

256

158

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Underwater gliders are autonomous underwater vehicles that profile vertically by changing their buoyancy and use wings to move horizontally. Gliders are useful for sustained observation at relatively fine horizontal scales, especially to connect the coastal and open ocean. In this review, research topics are grouped by time and length scales. Large-scale topics addressed include the eastern and western boundary currents and the regional effects of climate variability. The accessibility of horizontal length scales of order 1 km allows investigation of mesoscale and submesoscale features such as fronts and eddies. Because the submesoscales dominate vertical fluxes in the ocean, gliders have found application in studies of biogeochemical processes. At the finest scales, gliders have been used to measure internal waves and turbulent dissipation. The review summarizes gliders' achievements to date and assesses their future in ocean observation.

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“…The assumption of geostrophic balance has been widely used in the literature to estimate along‐shelf baroclinic transport in river plumes, both from numerical model results (e.g., Fong & Geyer, ; Moffat & Lentz, ; Pimenta & Kirwan, ; Pimenta et al, ) and observations (e.g., Chant et al, ; Chant et al, ; Geyer et al, ; Mazzini et al, ). Pimenta et al () provided a thorough discussion of scalings to estimate plume baroclinic transports under the assumption of geostrophic balance.…”

Section: Discussionmentioning

confidence: 99%

The Impact of Wind Forcing on the Thermal Wind Shear of A River Plume

et al. 2019

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A 38-day long time series obtained using a combination of moored Wirewalkers equipped with conductivity-temperature-depth profilers and bottom-mounted and subsurface acoustic Doppler current profilers provided detailed high-resolution observations that resolved near-surface velocity and vertical and cross-shelf density gradients of the Chesapeake Bay plume far field. This unprecedented data set allowed for a detailed investigation of the impact of wind forcing on the thermal wind shear of a river plume. Our results showed that thermal wind balance was a valid approximation for the cross-shelf momentum balance over the entire water column during weak winds (| w | < 0.075 Pa), and it was also valid within the interior during moderate downwelling (−0.125< w < −0.075 Pa). Stronger wind conditions, however, resulted in the breakdown of the thermal wind balance in the Chesapeake Bay plume, with thermal wind shear overestimating the observed shear during downwelling and underestimating during upwelling conditions. A momentum budget analysis suggests that viscous stresses from wind-generated turbulence are mainly responsible for the generation of ageostrophic shear.Plain Language Summary Historically, oceanographers have been using a theoretical framework that allows us to estimate current velocities from water density profiles, commonly obtained during oceanographic cruises. This technique has been used to calculate transport of water and heat carried by the Gulf Stream toward the poles and to study other major currents in the deep ocean. The same theoretical framework has also been applied to study currents in shallow coastal regions (10-20-m), however, without a thorough validation. In this work, we test and validate this theoretical framework in the Chesapeake Bay Plume, which is brackish water originated from the Chesapeake Bay off the coasts of Virginia and North Carolina. We use novel high-resolution measurements obtained by a series of moored instruments that include current meters and two Wirewalkers, which are wave-powered profiling platforms that were equipped with salinity and temperature sensors and that allowed us to obtain a rich data set with thousands of density profiles. We found that theory and observations agree when winds are weak or moderate. However, during strong winds, we found that the theory breaks down due to wind-generated turbulence (irregular motion resulting from eddies), and a correction for using this theory in shallow areas is necessary.

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Buoyancy-Driven Coastal Currents off Oregon during Fall and Winter

Cited by 49 publications

References 55 publications

Optics of the offshore Columbia River plume from glider observations and satellite imagery

Optics of the offshore Columbia River plume from glider observations and satellite imagery

Ocean Research Enabled by Underwater Gliders

The Impact of Wind Forcing on the Thermal Wind Shear of A River Plume

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