Ocean nutrient pathways associated with the passage of a storm

Rumyantseva, Anna; Lucas, Natasha; Rippeth, Tom P.; Martin, Adrian P.; Painter, Stuart C.; Boyd, T.; Henson, Stephanie A.

doi:10.1002/2015gb005097

Cited by 39 publications

(53 citation statements)

References 40 publications

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“…These results are qualitatively similar under the weaker stress, but the changes in column‐integrated ⟨ N ⟩ x , y and ⟨ P ⟩ x , y are about 1/3 to 1/2 as large, which is qualitatively consistent with less deepening of the MLD 3 and less nutrient entrainment under weaker wind stress (Figure S5). In addition, this evolution is qualitatively consistent with expectations based on available observations of the nutrient and/or chlorophyll responses to autumn storm passage (e.g., Babin et al, ; Rumyantseva et al, ).…”

Section: Resultssupporting

confidence: 89%

“…It is difficult to observe all the variables and spatiotemporal scales necessary to evaluate the hypotheses emerging from these simulations, but there are many observations of the bio‐optical and physical response of the upper‐ocean to a summer or autumn storm from satellites (e.g., Babin et al, ; Carranza & Gille, ; Fauchereau et al, ; Lin et al, ; Lin, ) and a rapidly increasing but small number of subsurface bio‐optical observations during and after storms from profiling subsurface floats (e.g., Chacko, ; Girishkumar et al, ; Ye et al, ). Like all our simulations, many of these prior observations, including the observations of Rumyantseva et al () and Painter et al (), which motivated the present study, show that autumn storms increase the surface density, deepen the mixed layer, erode subsurface chlorophyll maxima and mix subsurface chlorophyll up toward the surface (thereby increasing the fraction of column‐integrated chlorophyll in the mixed layer), and trigger an increase in column‐integrated chlorophyll. However, the magnitude and qualitative nature of these responses are highly variable between different storms (see, e.g., Painter et al, ) due to the wide variety of different physical and biogeochemical circumstances in which storms occur.…”

Section: Conclusion and Discussionsupporting

confidence: 87%

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Submesoscales Enhance Storm‐Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

Lévy

Taylor

2019

JGR Oceans

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Storms deepen the mixed layer, entrain nutrients from the pycnocline, and fuel phytoplankton blooms in midlatitude oceans. However, the effects of oceanic submesoscale (0.1-10 km horizontal scale) physical heterogeneity on the physical-biogeochemical response to a storm are not well understood. Here, we explore these effects numerically in a Biogeochemical Large Eddy Simulation (BLES), where a four-component biogeochemical model is coupled with a physical model that resolves some submesoscales and some smaller turbulent scales (2 km to 2 m) in an idealized storm forcing scenario. Results are obtained via comparisons to BLES in smaller domains that do not resolve submesoscales and to one-dimensional column simulations with the same biogeochemical model, initial conditions, and boundary conditions but parameterized turbulence and submesoscales. These comparisons show different behaviors during and shortly after the storm. During the storm, resolved submesoscales double the vertical nutrient flux. The vertical diffusivity is increased by a factor of 10 near the mixed layer base, and the mixing-induced increase in potential energy is double. Resolved submesoscales also enhance horizontal nutrient and phytoplankton variance by a factor of 10. After the storm, resolved submesoscales maintain higher nutrient and phytoplankton variance within the mixed layer. However, submesoscales reduce net vertical nutrient fluxes by 50% and nearly shut off the turbulent diffusivity. Over the whole scenario, resolved submesoscales double storm-driven biological production. Current parameterizations of submesoscales and turbulence fail to capture both the enhanced nutrient flux during the storm and the enhanced biological production.

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Section: Resultssupporting

confidence: 89%

Section: Conclusion and Discussionsupporting

confidence: 87%

Submesoscales Enhance Storm‐Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

Lévy

Taylor

2019

JGR Oceans

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“…If the surface layer is stirred by strong wind and mixed with the subsurface low pCO sea 2 layer, the surface will act as a further CO 2 sink. Several reports indicate that the strong wind associated with the passage of low pressure systems deepens the surface mixed layer and has impacts on the biogeochemistry (Wada et al, 2011;Rumyantseva et al, 2015). Simmonds and Keay (2009) reported that the strength of cyclones in the Arctic Ocean is increasing with the long-term reduction of sea-ice cover.…”

Section: Future Direction Of Hidden Co 2 Sink In the Canada Basinmentioning

confidence: 99%

Low <i>p</i>CO<sub>2</sub> under sea-ice melt in the Canada Basin of the western Arctic Ocean

et al. 2017

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Abstract. In September 2013, we observed an expanse of surface water with low CO 2 partial pressure (pCO sea 2 ) (< 200 µatm) in the Chukchi Sea of the western Arctic Ocean. The large undersaturation of CO 2 in this region was the result of massive primary production after the sea-ice retreat in June and July. In the surface of the Canada Basin, salinity was low (< 27) and pCO sea 2 was closer to the air-sea CO 2 equilibrium (∼ 360 µatm). From the relationships between salinity and total alkalinity, we confirmed that the low salinity in the Canada Basin was due to the larger fraction of meltwater input (∼ 0.16) rather than the riverine discharge (∼ 0.1). Such an increase in pCO sea 2 was not so clear in the coastal region near Point Barrow, where the fraction of riverine discharge was larger than that of sea-ice melt. We also identified low pCO sea 2 (< 250 µatm) in the depth of 30-50 m under the halocline of the Canada Basin. This subsurface low pCO sea 2 was attributed to the advection of Pacific-origin water, in which dissolved inorganic carbon is relatively low, through the Chukchi Sea where net primary production is high. Oxygen supersaturation (> 20 µmol kg −1 ) in the subsurface low pCO sea 2 layer in the Canada Basin indicated significant net primary production undersea and/or in preformed condition. If these low pCO sea 2 layers surface by wind mixing, they will act as additional CO 2 sinks; however, this is unlikely because intensification of stratification by sea-ice melt inhibits mixing across the halocline.

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“…According to the turbulence activity parameter, the intermediate regime of turbulence dominates between the base of the SML and the 1,026.2 isopycnals (not shown). At those depths, vigorous patches of

κ_{ρ}

play an important role in the turbulent flux of conservative and nonconservative properties, which can be estimated from

F_{c} = - κ_{ρ} \frac{\partial C}{\partial z},

where

\partial C false/ \partial z

is the vertical gradient of a scalar property C (e.g., Doubell et al, ; Kaneko et al, ; Rumyantseva et al, ).…”

Section: Turbulence Observationsmentioning

confidence: 99%

“…Chlorophyll‐a fluorescence is the most commonly used index of phytoplankton biomass which is controlled primarily by the nutrient (nitrate) transport within the ocean (Sarmiento & Gruber, ). The density‐nitrate relationship was applied to the microstructure‐derived density to estimate the microscale vertical distribution of nitrate (e.g., Rumyantseva et al, ; Sharples et al, ). One advantage of having a reliable density‐nitrate relationship is that measurements of the nitrate gradient and turbulent diffusivity can be obtained via the same instrument at the same time.…”

Section: Turbulence Observationsmentioning

confidence: 99%

On the Role of Turbulent Mixing Produced by Vertical Shear Between the Brazil Current and the Intermediate Western Boundary Current

et al. 2020

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An intensification of the vertical shear is observed below the surface mixed layer at 21 • S due to the mutually opposing flows of the Brazil Current and the Intermediate Western Boundary Current. The propensity to develop turbulence and mixing due to vertical shear over intense stabilizing density gradients is an important characteristic of such environments. For the first time, microscale measurements were made in the Brazil Current-Intermediate Western Boundary Current system, providing direct quantitative values of the turbulent fluctuations. Peaks of relative strong dissipation rates of turbulent kinetic energy (O(10 −8 ) W/kg) were observed close to the base of the surface mixed layer. On the other hand, prominent peaks of turbulent kinetic energy dissipation rates of up to 2 orders of magnitude higher than the background were observed at deeper levels, where stratification begins to lose intensity. Analyzing such peaks, caused by intense vertical shear or weak stratification-and sometimes both-, allows a characterization of the local mixing processes and the role played by vertical exchanges of biogeochemical properties. Based on the estimated nitrate gradient and the vertical diffusivity, we show that turbulent mixing driven by vertical shear plays an important role in the supply of nitrate to the upper layer.Plain Language Summary Turbulent mixing across the density surfaces can bring nutrient-rich waters from the subsurface to the upper sunlit layer of the ocean, therefore, modulating the primary productivity in an oligotrophic ocean. Based on measurements of small-scale shear variance, we found that the interaction between the poleward-flowing Brazil Current and the Intermediate Western Boundary Current flowing underneath in the opposite direction enhances the upper-ocean mixing through shear instabilities. The destabilizing influence of the velocity shear overcomes the stabilizing effect of the stratification. The mixing on the interface between these two western boundary currents may provide an important route for local nutrient exchanges.

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Ocean nutrient pathways associated with the passage of a storm

Cited by 39 publications

References 40 publications

Submesoscales Enhance Storm‐Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

Submesoscales Enhance Storm‐Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

Low <i>p</i>CO<sub>2</sub> under sea-ice melt in the Canada Basin of the western Arctic Ocean

On the Role of Turbulent Mixing Produced by Vertical Shear Between the Brazil Current and the Intermediate Western Boundary Current

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Ocean nutrient pathways associated with the passage of a storm

Cited by 39 publications

References 40 publications

Submesoscales Enhance Storm‐Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

Submesoscales Enhance Storm‐Driven Vertical Mixing of Nutrients: Insights From a Biogeochemical Large Eddy Simulation

Low &lt;i&gt;p&lt;/i&gt;CO&lt;sub&gt;2&lt;/sub&gt; under sea-ice melt in the Canada Basin of the western Arctic Ocean

On the Role of Turbulent Mixing Produced by Vertical Shear Between the Brazil Current and the Intermediate Western Boundary Current

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Low <i>p</i>CO<sub>2</sub> under sea-ice melt in the Canada Basin of the western Arctic Ocean