Cross‐shore tracer exchange between the surfzone and inner‐shelf

Hally-Rosendahl, Kai; Feddersen, Falk; Guza, R. T.

doi:10.1002/2013jc009722

Cited by 53 publications

(75 citation statements)

References 58 publications

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“…This paper emphasizes the transition to depth‐uniformity with increasing wave breaking, but outside the surfzone stratification likely played an important role. Richardson numbers suggested substantial inhibition of vertical mixing by stratification outside the surfzone, whereas previous work suggests that breaker‐induced mixing if often sufficient to eliminate most stratification inside the surfzone (Hally‐Rosendahl et al, ; Kumar & Feddersen, ). Observations outside the surfzone were further complicated by the presence of significant divergent motions at eddy frequencies (i.e., eddy kinetic energy only 1.2–2.2 times greater than potential).…”

Section: Summary and Discussionmentioning

confidence: 86%

“…Inside the surfzone, Richardson number, which does not account for breaker‐induced mixing, may become less relevant. Previous studies suggest that breaker‐induced mixing is often sufficient to eliminate stratification in the surfzone (Hally‐Rosendahl et al, ; Kumar & Feddersen, ).…”

Section: Resultsmentioning

confidence: 98%

“…We estimated

Δ ρ

at X1 by assuming (i) that near‐surface density at X1 equaled near‐surface density measured in 8 m depth and (ii) that density near the seabed elevation

z = - h

at X1 equaled the density at the same elevation in the 8 m profile (similarly for other instrument locations). This likely overestimates Ri , since

Δ ρ

likely decreases onshore of 8 m (Hally‐Rosendahl et al, ; Kumar & Feddersen, ). Both outside and inside the surfzone, bin‐averaged Ri exceeded 0.05 in all but one case (not shown; the exception was X1 for

H_{n d} / h = 1.34

).…”

Section: Resultsmentioning

confidence: 99%

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Depth Dependence of Nearshore Currents and Eddies

et al. 2017

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The three‐dimensional (across‐shore, alongshore, and vertical) structure of hourly mean currents and <0.01 Hz eddies was measured on a natural beach using 12 Acoustic Doppler Profilers. Both eddies and alongshore currents became relatively depth‐uniform inside the surfzone. Eddies showed greater depth dependence than alongshore currents. A two‐layer model, derived by scaling of the wave‐averaged shallow water equations, yielded separate equations for depth‐averaged and depth‐dependent velocity components. Scaling suggests, and observations confirm, only a small role for lateral advection in most surfzone cases, leading to one‐dimensional vertical models for depth dependence. For alongshore currents, depth dependence is generated by opposite forcing on lower and upper layers, respectively by bottom friction (quantified by time scale λb−1) and waves or wind. This generation is balanced by mixing between upper and lower layers (time scale λm−1), so the ratio between depth‐dependent and depth‐averaged alongshore currents equals λb/λm. Established models for bottom friction and breaker‐induced mixing predicted a surfzone reduction in λb/λm consistent with the observed reduction in alongshore current depth dependence. Scatter around trends was considerable. Alongshore variability was significant for depth‐dependence of currents and eddies. Inside (but not outside) the surfzone, the mixing time scale λm−1 was shorter than the eddy period, so a quasi‐steady balance was predicted between forcing and mixing of eddy depth dependence. Observed eddy depth dependence exceeded predictions for barotropic eddies generated by shear production (i.e., shear instabilities), possibly indicating generation of eddies by random breaking waves in the surfzone, or indicating baroclinic effects outside the surfzone.

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Section: Summary and Discussionmentioning

confidence: 86%

Section: Resultsmentioning

confidence: 98%

“…We estimated

Δ ρ

at X1 by assuming (i) that near‐surface density at X1 equaled near‐surface density measured in 8 m depth and (ii) that density near the seabed elevation

z = - h

at X1 equaled the density at the same elevation in the 8 m profile (similarly for other instrument locations). This likely overestimates Ri , since

Δ ρ

H_{n d} / h = 1.34

).…”

Section: Resultsmentioning

confidence: 99%

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Depth Dependence of Nearshore Currents and Eddies

et al. 2017

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“…Transport of freshwater from a river entering the surf zone could be reasonably expected to be influenced by surf zone circulation processes, as has been shown for passive tracers (Brown et al, ; Clark et al, ; Hally‐Rosendahl et al, ). The strongest surf zone circulation is driven in the alongshore direction by obliquely directed breaking waves (Feddersen et al, ; Longuet‐Higgins, ).…”

Section: Introductionmentioning

confidence: 88%

“…Small river mouths are often unengineered, allowing surf zone wave breaking to occur near or at such outflows. In regions with higher population densities, engineered structures such as jetties are present at most river mouths, preventing wave breaking and the influence of surf zone dynamics on buoyancy and momentum‐driven river plume processes (Clark et al, ; Hally‐Rosendahl et al, ; Horner‐Devine et al, ).…”

Section: Introductionmentioning

confidence: 99%

A Conceptual Model of a River Plume in the Surf Zone

2019

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We use observations from the Quinault River, a small river that flows into an energetic surf zone on the West Coast of Washington state, to investigate the interaction between river and wave forcing. By synthesizing data from moorings, drifters, and Unmanned Aerial System video, we develop a conceptual model of this interaction based on three length scales: the surf zone width, L SZ ; the near-field plume length, L NF ; and the cross-shore extent of the channel, L C . The relationships between these length scales show how tidal variability and bathymetric effects change the balance of wave and river momentum. The most frequently observed state is L SZ > L NF . Under these conditions the surf zone traps the outflowing river plume and the river water's initial propagation into the surf zone is set by L NF . When the river velocity is highest during low water, and when wave forcing is low, L NF > L SZ and river water escapes the surf zone. At high water during low wave forcing, L C > L SZ , such that minimal wave breaking occurs in the channel and river water escapes onto the shelf. Based on the discharge, wave, and tidal conditions, the conceptual model is used to predict the fate of river water from the Quinault over a year, showing that approximately 70% of the river discharge is trapped in the surf zone upon exiting the river mouth.Plain Language Summary Small rivers are an important source of sediment, nutrients, and pollutants to the coastal ocean, but they are less well studied than their larger siblings. The coastal discharge from small rivers often meets large breaking waves in the surf zone. Our work investigates the effect of the large waves present at the mouth of one such river, the Quinault River in Washington State. We find that the fate of Quinault River water is determined by the relative importance of river, wave, and depth effects, all of which are modulated by the tide. When wave forcing dominates, river water is trapped in the surf zone. When river forcing dominates, river water escapes the surf zone. The difference in depth between the offshore channel and the rest of the beach can also allow river water to escape the surf zone by reducing the effect of the wave forcing. When we apply our conceptual model to 1 year of wave, river, and tide data, we predict that 70% of Quinault River discharge is trapped in the surf zone. The sediment and pollutants carried by this trapped river water can thus have important impacts on beach erosion, public health, and local ecology.Small river mouths are often unengineered, allowing surf zone wave breaking to occur near or at such outflows. In regions with higher population densities, engineered structures such as jetties are present at most river mouths, preventing wave breaking and the influence of surf zone dynamics on buoyancy and

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The surf zone heat budget: The effect of wave heating

Sinnett

Feddersen

2014

Geophysical Research Letters

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Surf zone incident wave energy flux is dissipated by wave breaking which through viscosity generates heat. This effect is not present in shelf heat budgets and has not previously been considered. Pier‐based observations of water temperature in 1–4 m depth, meteorology, and waves are used to test a surf zone heat budget, which closes on diurnal and longer time scales. Wave energy flux is the second most variable term with mean contribution one fourth of the mean short‐wave radiation. The heat budget residual has semidiurnal and higher‐frequency variability and net cooling. Cross‐shore advective heat flux driven by internal wave events, rip currents, and undertow contribute to this residual variability and net cooling. In locations with large waves, steeper beaches, or less solar radiation, the ratio of wave energy flux to short‐wave radiation may be >1.

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Cross‐shore tracer exchange between the surfzone and inner‐shelf

Cited by 53 publications

References 58 publications

Depth Dependence of Nearshore Currents and Eddies

Depth Dependence of Nearshore Currents and Eddies

A Conceptual Model of a River Plume in the Surf Zone

The surf zone heat budget: The effect of wave heating

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