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  • <sc>Fig</sc>. 1.
    View in gallery
    Fig. 1.

    Array of near-bottom acoustic Doppler current meters deployed in about 4.5-m water depth approximately 300 m from the shoreline. ADVF and ADVO are SonTek field and ocean probes, respectively

  • <sc>Fig</sc>. 2.
    View in gallery
    Fig. 2.

    Locations of instruments (labeled) and contours of water depth (in m below mean sea level every 0.5 m) for yearday 226. Each compact array (CA6 and CA7) contained six accurately (±0.5 m) surveyed bottom-mounted pressure sensors (small filled circles) and one current meter located about 0.5 m above the bottom near the center of the array (not shown) (Herbers et al. 2000, submitted to J. Phys. Oceanogr.). The shoreline location was centered approximately at cross-shore location = 125 m, with ≃ ±10 m cross-shore fluctuations caused by the 1-m tidal range. The bathymetry seaward of about 3.5-m depth did not change significantly during the experiment

  • <sc>Fig</sc>. 3.
    View in gallery
    Fig. 3.

    (a) Alongshore wind stress, (b) significant wave height, (c) cross-shore gradient of wave-induced energy flux, and (d) cross-shore gradient of wave-induced radiation stress vs time

  • <sc>Fig</sc>. 4.
    View in gallery
    Fig. 4.

    (a) Cross-shore velocity (negative is offshore-directed flow), (b) alongshore velocity (positive is flow toward the south), (c) cross-shore gradient of alongshore velocity, and (d) percent of valid data from the malfunctioning ADVO vs time

  • <sc>Fig</sc>. 5.
    View in gallery
    Fig. 5.

    Energy density spectra from (a) velocity time series and (b) modified according to (6) and (7). Solid curves are Puu + Pυυ and dashed curves are Pww. (c) Integral of cospectrum of velocity differences vs frequency. Data are from 25-min-long ADVO records obtained at 12:00 (EST) on yearday 236. The burst-averaged cross-shore and alongshore currents were −0.02 and 0.10 m s−1, respectively, and the significant wave height was 1.0 m

  • <sc>Fig</sc>. 6.
    View in gallery
    Fig. 6.

    Estimates of near-bottom stress using (a) single and (b) dual sensors vs time. (b) Estimates from the pair of ADVOs and ADVFs are shown as solid and dashed curves, respectively

  • <sc>Fig</sc>. 7.
    View in gallery
    Fig. 7.

    (a) Sum of wind and wave forcing and (b) near-bottom turbulent Reynolds shear stress vs time

  • <sc>Fig</sc>. 8.
    View in gallery
    Fig. 8.

    (a) Shear production of turbulent kinetic energy, (b) dissipation of turbulent kinetic energy, and (c) depth-averaged rate of energy extraction from the shoaling wave field vs time. The vertical scale in (c) is different than in (a) and (b)

  • <sc>Fig</sc>. 9.
    View in gallery
    Fig. 9.

    (a) Covariance, (b) log profile, and (c) drag law estimates of turbulent Reynolds shear stress vs time

Fig. 1.

Array of near-bottom acoustic Doppler current meters deployed in about 4.5-m water depth approximately 300 m from the shoreline. ADVF and ADVO are SonTek field and ocean probes, respectively
Fig. 2.

Locations of instruments (labeled) and contours of water depth (in m below mean sea level every 0.5 m) for yearday 226. Each compact array (CA6 and CA7) contained six accurately (±0.5 m) surveyed bottom-mounted pressure sensors (small filled circles) and one current meter located about 0.5 m above the bottom near the center of the array (not shown) (Herbers et al. 2000, submitted to J. Phys. Oceanogr.). The shoreline location was centered approximately at cross-shore location = 125 m, with ≃ ±10 m cross-shore fluctuations caused by the 1-m tidal range. The bathymetry seaward of about 3.5-m depth did not change significantly during the experiment
Fig. 3.

(a) Alongshore wind stress, (b) significant wave height, (c) cross-shore gradient of wave-induced energy flux, and (d) cross-shore gradient of wave-induced radiation stress vs time
Fig. 4.

(a) Cross-shore velocity (negative is offshore-directed flow), (b) alongshore velocity (positive is flow toward the south), (c) cross-shore gradient of alongshore velocity, and (d) percent of valid data from the malfunctioning ADVO vs time
Fig. 5.

Energy density spectra from (a) velocity time series and (b) modified according to (6) and (7). Solid curves are Puu + Pυυ and dashed curves are Pww. (c) Integral of cospectrum of velocity differences vs frequency. Data are from 25-min-long ADVO records obtained at 12:00 (EST) on yearday 236. The burst-averaged cross-shore and alongshore currents were −0.02 and 0.10 m s−1, respectively, and the significant wave height was 1.0 m
Fig. 6.

Estimates of near-bottom stress using (a) single and (b) dual sensors vs time. (b) Estimates from the pair of ADVOs and ADVFs are shown as solid and dashed curves, respectively
Fig. 7.

(a) Sum of wind and wave forcing and (b) near-bottom turbulent Reynolds shear stress vs time
Fig. 8.

(a) Shear production of turbulent kinetic energy, (b) dissipation of turbulent kinetic energy, and (c) depth-averaged rate of energy extraction from the shoaling wave field vs time. The vertical scale in (c) is different than in (a) and (b)
Fig. 9.

(a) Covariance, (b) log profile, and (c) drag law estimates of turbulent Reynolds shear stress vs time
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Editorial Type:
Article
Article Type:
Research Article

Turbulence Measurements in the Surf Zone

John TrowbridgeWoods Hole Oceanographic Institution, Woods Hole, Massachusetts

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Steve ElgarWoods Hole Oceanographic Institution, Woods Hole, Massachusetts

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Print Publication:
01 Aug 2001
DOI:
https://doi.org/10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2
Page(s):
2403–2417
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Abstract

Velocity measurements within 1 m of the bottom in approximately 4.5-m water depth on a sand beach provide estimates of turbulent Reynolds shear stress, using a dual-sensor technique that removes contamination by surface waves, and inertial-range estimates of dissipation. When combined with wave measurements along a cross-shore transect and nearby wind measurements, the dataset provides direct estimates of the terms in simplified equations for alongshore momentum and turbulence energetics and permits examination of semiempirical relationships between bottom stress and near-bottom velocity. The records are dominated by three events when the measurement site was in the outer part of the surf zone. Near-bottom turbulent shear stress is well correlated with (squared correlation coefficient r2 = 0.63), but smaller than (regression coefficient b = 0.51 ± 0.03 at 95% confidence), wind stress minus cross-shore gradient of wave-induced radiation stress, indicating that estimates of one or more of these terms are inaccurate or that an additional effect was important in the alongshore momentum balance. Shear production of turbulent kinetic energy is well correlated (r2 = 0.81) and consistent in magnitude (b = 1.1 ± 0.1) with dissipation, and both are two orders of magnitude smaller than the depth-averaged rate at which the shoaling wave field lost energy to breaking, indicating that breaking-induced turbulence did not penetrate to the measurement depth. Log-profile estimates of stress are well correlated with (r2 = 0.75), but larger than (b = 2.3 ± 0.1), covariance estimates of stress, indicating a departure from the Prandtl–von Kármán velocity profile. The bottom drag coefficient was (1.9 ± 0.2) × 10−3 during unbroken waves and approximately half as large during breaking waves.

Corresponding author address: Dr. John H. Trowbridge, WHOI, Woods Hole, MA 02543. Email: jtrowbridge@whoi.edu

Abstract

Velocity measurements within 1 m of the bottom in approximately 4.5-m water depth on a sand beach provide estimates of turbulent Reynolds shear stress, using a dual-sensor technique that removes contamination by surface waves, and inertial-range estimates of dissipation. When combined with wave measurements along a cross-shore transect and nearby wind measurements, the dataset provides direct estimates of the terms in simplified equations for alongshore momentum and turbulence energetics and permits examination of semiempirical relationships between bottom stress and near-bottom velocity. The records are dominated by three events when the measurement site was in the outer part of the surf zone. Near-bottom turbulent shear stress is well correlated with (squared correlation coefficient r2 = 0.63), but smaller than (regression coefficient b = 0.51 ± 0.03 at 95% confidence), wind stress minus cross-shore gradient of wave-induced radiation stress, indicating that estimates of one or more of these terms are inaccurate or that an additional effect was important in the alongshore momentum balance. Shear production of turbulent kinetic energy is well correlated (r2 = 0.81) and consistent in magnitude (b = 1.1 ± 0.1) with dissipation, and both are two orders of magnitude smaller than the depth-averaged rate at which the shoaling wave field lost energy to breaking, indicating that breaking-induced turbulence did not penetrate to the measurement depth. Log-profile estimates of stress are well correlated with (r2 = 0.75), but larger than (b = 2.3 ± 0.1), covariance estimates of stress, indicating a departure from the Prandtl–von Kármán velocity profile. The bottom drag coefficient was (1.9 ± 0.2) × 10−3 during unbroken waves and approximately half as large during breaking waves.

Corresponding author address: Dr. John H. Trowbridge, WHOI, Woods Hole, MA 02543. Email: jtrowbridge@whoi.edu

1. Introduction

Turbulence is believed to have a dominant effect on flows and sediment transport in the surf zone. For example, often it is assumed that a balance between bottom stress and cross-shore gradient of wave-induced radiation stress controls the alongshore flow driven by breaking waves (e.g., Battjes 1988) and that the effect of bottom stress is transmitted through the water column by turbulence with scales much smaller than the water depth (e.g., Svendsen and Putrevu 1994). Breaking-induced turbulence dominates wave energy dissipation in the surf zone (Thornton and Guza 1986). Many models of sediment transport are based on the assumptions that near-bottom turbulent shear stress controls the entrainment of sediment from the seafloor (e.g., Glenn and Grant 1987) and that turbulence maintains suspended sediment in the water column (e.g., Fredsoe and Deigaard 1992; Nielsen 1992).

Despite the importance of turbulence in conceptual and mathematical models of surf zone processes, direct measurements of surf zone turbulence have been rare. Separation of turbulence from waves is difficult because turbulent velocity fluctuations typically are two to three orders of magnitude less energetic than wave motions. As a result, previous surf zone turbulence measurements have focused on velocity fluctuations at frequencies far higher than those of the waves, resulting in estimates of dissipation, but not stress (George et al. 1994), or they have have been obtained in laboratory basins (e.g., Ogston et al. 1995; Ting and Kirby 1996), where phase-averaging techniques appropriate for monochromatic waves, which are not applicable in random ocean waves, are used to separate waves from turbulence. Most estimates of nearshore turbulence statistics have been obtained indirectly from measurements of waves and winds. For example, depth-integrated dissipation has been estimated as the residual in a wave energy balance (Thornton and Guza 1986; Kaihatu and Kirby 1995; Elgar et al. 1997; Herbers et al. 2000), and bottom stress has been estimated as the residual in an alongshore momentum balance (Thornton and Guza 1986; Whitford and Thornton 1996; Feddersen et al. 1998; Lentz et al. 1999).

Here, surf zone measurements of near-bottom velocity designed to produce direct covariance estimates of turbulent Reynolds shear stress and inertial-range estimates of turbulence dissipation are presented. The turbulence measurements were obtained within a cross-shelf transect of arrays of pressure sensors, which determine the wave field, and near an anemometer and a profiling velocimeter, which determine wind forcing and vertical structure of currents. The analysis focuses on estimation of terms in four equations that are commonly used to describe surf zone processes. The first is an alongshore momentum equation, in which wind stress and cross-shore gradient of wave-induced radiation stress balance near-bottom turbulent Reynolds shear stress (e.g., Mei 1983):
i1520-0485-31-8-2403-e1
The second is a hybrid of a balance between dissipation and shear production of turbulent kinetic energy, known to hold in the wall region of turbulent boundary layers (e.g., Tennekes and Lumley 1972), and a simplified model of surf zone energetics (Battjes 1975), in which dissipation balances the depth-averaged rate at which breaking extracts energy from the shoaling wave field:
i1520-0485-31-8-2403-e2
The third is the Prandtl–von Kármán representation of the velocity profile in a turbulent boundary layer (e.g., Tennekes and Lumley 1972):
i1520-0485-31-8-2403-e3
which has been used in the surf zone to estimate stress from measurements of horizontal velocity (Garcez-Faria et al. 1998). The fourth is a quadratic drag law:
i1520-0485-31-8-2403-e4
commonly used to represent bottom stress in models of nearshore processes (e.g., Bowen 1969; Longuet-Higgins 1970).

In (1)–(4), x, y, and z are coordinates in a right-handed system with x positive onshore, y positive alongshore, and z positive upward, where z = −h and z = η represent the seafloor and water surface, respectively. The quantity ρ0 is a fixed reference density, (u, υ, w) is the velocity vector, primes denote turbulent fluctuations, −ρ0υw is the alongshore component of the turbulent Reynolds shear stress, ϵ is the turbulence dissipation rate, Fx is the cross-shore component of the wave-induced energy flux, Sxy is the off-diagonal component of the wave-induced radiation stress tensor, τwy is the alongshore component of the wind stress, κ is the empirical von Kármán constant (approximately equal to 0.40), and cd is an empirical drag coefficient. An overbar represents a time average over a period long compared with the timescales of waves and turbulence, but short relative to the timescales of variability of the forcing. The wind stress, energy flux, radiation stress, and dissipation are averaged over the same time period. The statistical properties of the flow are assumed to be stationary over the averaging period and independent of alongshore position. The quantity −ρ0υw is evaluated at a height above bottom that is small compared with the water depth, but large relative to the scale of the bottom roughness elements, so that it represents the stress transmitted to the seafloor. The stress-transmitting turbulence is assumed to be distinguishable from other motions because of its small spatial scales, believed to be a small fraction of the water depth (e.g., Svendsen and Putrevu 1994).

2. Methods

a. Measurements

The turbulence measurements, described in detail by Fredericks et al. (2001), were acquired between 25 August (yearday 236) and 21 November (yearday 324) of 1997 on a sandy Atlantic beach near Duck, North Carolina, at the U.S. Army Corps of Engineers Field Research Facility. An array of five upward-looking Sontek acoustic Doppler velocimeters (ADVs) was mounted on a low-profile frame (Fig. 1). The ADVs measure the three-dimensional velocity vector in a sample volume with a spatial scale of approximately 0.01 m (e.g., Voulgaris and Trowbridge 1998) and perform well in the surf zone (Elgar et al. 2001). The array included three of the field version of Sontek's acoustic Doppler velocimeter (ADVF) and two of the more rugged ocean version (ADVO), one of which was fitted with pressure, temperature, pitch, and roll sensors, as well as compass. The ADVOs shared a common logger that sampled the two sensors simultaneously at 7 Hz in one burst of 25 minutes each hour. The ADVFs shared a separate common logger that sampled the three sensors simultaneously at 25 Hz in one burst of 10 minutes each hour. The ADV frame was approximately 300 m from the shoreline and 300 m north of the Field Research Facility (FRF: Fig. 2). The ADVs occupied an on–offshore line along the frame's northern edge, upstream of the frame itself, relative to the predominantly southerly wind- and wave-driven flows. The bathymetry near the measurement site is approximately uniform in the alongshore direction on scales of kilometers (Birkemeier et al. 1985; Lentz et al. 1999), although there is a cross-shore channel approximately 100 m wide and 1 m deep beneath the pier (Fig. 2).

Other instrumentation included 12 Setra pressure sensors making up “compact arrays” 6 and 7 (CA6 and CA7), centered approximately 40 m onshore and 80 m offshore of the ADV frame, respectively (Herbers et al. 2000, submitted to J. Phys. Oceanogr.) two Marsh–McBirney two-axis electromagnetic current meters, located near the centers of CA6 and CA7; a Solent sonic anemometer, located on a mast at the end of the FRF pier approximately 20 m above the water surface; and a Sontek 3-MHz acoustic Doppler profiler (ADP), located approximately 170 m north of the ADV frame (Fig. 2). The pressure sensors and two-axis velocimeters were sampled nearly continuously at 2 Hz, the sonic anemometer was sampled continuously at 21 Hz, and the ADP sampled continuously in 0.25-m range bins at 25 Hz.

The ADV array experienced several problems. Estimates of wave angles indicate that the head of the offshore ADVF began rotating intermittently immediately after deployment. Approximately six days after deployment, the offshore ADVO began malfunctioning, and intermittently produced invalid data, characterized by intervals with velocities of precisely zero or poor correlation with velocities measured by the other ADVO. The ADVO measurements of acoustical backscatter intensity are clipped (i.e., do not exceed a fixed maximum value) during strong flows, which precludes use of this measurement to infer sediment concentration. Approximately ten days after deployment, the two onshore ADVFs were destroyed by large waves and strong currents. Divers reported that a scour hole with a depth of roughly 0.2 m formed beneath the ADV frame within a few days of deployment and that sand worms colonized the frame during the final two weeks, terminating useful data on approximately 27 October (yearday 299).

b. Analysis

The analysis focuses on data produced by the ADVOs and the two onshore ADVFs during the first six days of the measurement period, when these four sensors functioned well, and on the remainder of the records produced by the ADVOs during intervals when the offshore ADVO produced valid data. To identify valid segments in the record produced by the offshore ADVO [see Fredericks et al. (2001) for details], the ADVO records were divided into 100-sample blocks, and the squared correlation coefficient r2 between cross-shore velocities at the two ADVOs was calculated for each block. Data from the intermittently functioning ADVO were assumed valid for blocks with r2 > 0.90. Thresholds of r2 = 0.90 and r2 = 0.80 produced nearly identical results.

Separate estimates of the alongshore component of turbulent Reynolds shear stress were obtained from the pair of ADVOs and from the onshore pair of ADVFs, by means of the dual-sensor procedure described by Trowbridge (1998):
i1520-0485-31-8-2403-e5
where Δυ and Δw are differences between alongshore and vertical velocities measured at two sensors, and cov is covariance. Equation (5) is based on the assumption that the stress-carrying turbulence has scales much smaller than scales of other motions, including in particular surface waves, and it requires that the sensor separation be such that the wave-induced velocities at the two sensors are nearly identical, while the corresponding turbulent velocities are uncorrelated. In addition to sampling variability, stress estimates based on (5) have a wave bias, caused by imperfect cancellation of wave-induced velocities by the differencing operation, and a turbulence bias, caused by nonzero correlation between turbulent velocity fluctuations at the two sensors. Estimates based on the analysis of Trowbridge (1998) indicate that the wave bias in the alongshore stress is an order of magnitude smaller than the alongshore stress itself in the present case. In contrast, wave biases in estimates of the cross-shore stress are similar in magnitude to the cross-shore stress so that the measurements provide only order-of-magnitude estimates of the cross-shore stress. The turbulence bias is discussed in section 4.
Estimates of dissipation were obtained from the onshore ADVO data by applying an inertial-range turbulence model to velocity spectra. The model, which describes frozen inertial-range turbulence advected past a fixed sensor by a steady horizontal current and random waves (Lumley and Terray 1983), was specialized (see the appendix) for frequencies large compared with the dominant wave frequency, unidirectional waves, and conditions near the seafloor, where wave-induced vertical velocities have a negligible effect on advection of turbulence. The model representation of the sum of the spectra of the two horizontal components of velocity is
i1520-0485-31-8-2403-e6
and the model representation of the spectrum of vertical velocity is
i1520-0485-31-8-2403-e7
where Puu, etc., are spectra, defined so that +∞−∞ Puu(ω) = variance; ω is radian frequency, equal to 2πf, where f is cyclic frequency; α is the empirical Kolmogorov constant, approximately equal to 1.5 (Grant et al. 1962); V is the magnitude of the current; σ2 is the variance of the wave-induced horizontal velocity; θ is the angle between waves and current; and I(σ/V, θ) is defined in the appendix. For each burst from the onshore ADVO, V, σ, and θ were set equal to the magnitude of the mean horizontal velocity, the standard deviation of the horizontal velocity, and the angle between the principal axes of the horizontal velocity fluctuations and the direction of the mean velocity, respectively. Burst-averaged velocity spectra Puu, etc., were obtained by combining spectra from Hanning windowed 100-sample segments. The noise level in (6) was estimated as the average of Puu + Pυυ over cyclic frequencies greater than 3 Hz. Two independent estimates of burst-averaged dissipation were obtained by averaging estimates of ω5/3[Puu(ω) + Pυυ(ω) − noise level] and ω5/3Pww(ω) over cyclic frequencies between 1 and 2 Hz, and solving (6) and (7) for ϵ. The two estimates are well correlated (r2 = 0.95) and approximately consistent in magnitude (regression slope b = 0.78 ± 0.1 at 95% confidence). The two estimates were then averaged to produce a single estimate of dissipation.

The estimates of dissipation are based on several considerations. Measured spectra are consistent with the model assumptions that Pww is noise-free and that Puu + Pυυ has a constant noise level (section 3; see also Elgar et al. 2001). The model fit is restricted to frequencies between 1 and 2 Hz because the measurements indicate applicability of (6) and (7) in this range (section 3) and because estimates of the spatial scales of turbulence corresponding to this range of frequencies, combined with atmospheric velocity spectra (Kaimal et al. 1968), indicate applicability of the inertial-range model. Equations (6) and (7) were not applied to ADVF data because, in contrast to the ADVO data, ω5/3 times spectral density minus noise for ADVF measurements was not constant at high frequency, instead exhibiting one or more peaks suggesting input of energy by flow disturbances produced by sensor supports and electronics, which were not far below the ADVF sample volumes (Fig. 1). High-frequency noise problems similarly precluded use of (6) and (7) with the offshore ADVO data.

Hour-averaged estimates of sea surface elevation variance, energy flux, and radiation stress in the wind wave frequency band (0.04 < f < 0.31 Hz) were obtained from the arrays of bottom-mounted pressure sensors using linear wave theory and a directional-moment-estimation technique (Elgar et al. 1994; Herbers et al. 1995; Herbers et al. 1999). Estimates obtained from the pressure arrays are well correlated and consistent in magnitude with independent estimates using linear theory from collocated measurements of pressure and velocity.

Records of Fx and Sxy at CA6 and CA7 were differenced to determine dFx/dx and dSxy/dx. Estimates of dSxy/dx are sensitive to errors in orientation, so a simplified procedure was used to estimate and correct for misalignment. The compact arrays CA6 and CA7 were assumed to be in coordinate systems rotated about the z axis by small angles γ(6) and γ(7) with respect to the isobath-aligned coordinate system. The radiation stress Sxy at compact array n in isobath-aligned coordinates is then (e.g., Jeffreys 1974)
S(n)xyŜ(n)xyγ(n)Ŝ(n)xxŜ(n)yyOγ2
where Ŝ(n)xx, etc., are components of the radiation stress tensor at array n in the slightly misaligned coordinate system. It follows from (8) that
i1520-0485-31-8-2403-e9
where Δ and subscript avg denote the difference and the average, respectively, of the values at CA6 and CA7. With the assumption that the misalignments are of similar magnitude but unequal (i.e., Δγ is order γavg), while differences between radiation stresses at CA6 and CA7 are small compared with the radiation stresses themselves (i.e., Δ[ŜxxŜyy] ≪ [ŜxxŜyy]avg), (9) approximates
SxyŜxyŜxxŜyyavgγ.
To estimate Δγ, ΔSxy was assumed equal to zero when the significant wave height Hs (four times the standard deviation of sea surface displacement) at CA7 was less than 1 m, corresponding to nonbreaking waves. For these conditions, ΔŜxy was regressed against −(ŜxxŜyy)avg, yielding Δγ = 3.1 ± 0.1 degrees at 95% confidence. Equation (10) with this value of Δγ was then used to compute ΔSxy at all times, including those when Hs > 1 m at CA7.

Hour-averaged estimates of τwy were determined from covariances of horizontal and vertical velocities computed from demeaned and detrended 10-min records from the sonic anemometer. These estimates are well correlated (r2 = 0.85) and consistent in magnitude (b = 1.35 ± 0.04) with independent estimates from a nearby mechanical anemometer (Fredericks et al. 2001).

Estimates of ∂u/∂z and ∂υ/∂z at approximately the measurement height of the ADVOs were obtained by differencing hour-averaged velocities in ADP bins 1 and 3, 0.63 and 1.13 m above the seafloor, respectively. The ADP data begin at yearday 262, so there are no estimates of velocity gradient for the first 26 days of the ADV record.

3. Results

During most of the measurement period, winds were weak, waves were small, and the 4.5-m-depth ADV site was seaward of the surf zone. During a few events, however, the alongshore wind stress approached 0.5 Pa (Fig. 3a), the significant wave height reached or exceeded 2 m (Fig. 3b), and shoreward-propagating waves lost energy flux (Fig. 3c) and produced a cross-shore gradient of wave-induced radiation stress (Fig. 3d), presumably because of breaking. The strong winds and breaking waves forced strong alongshore currents (Fig. 4b), in some cases accompanied by strong cross-shore currents (Fig. 4a), particularly during three events centered on days 246, 263, and 292. During these events, υ and ∂υ/∂x had the same sign (Figs. 4b and 4c), suggesting that the ADV site was in the outer part of the surf zone, because the strength of the alongshore current increased with increasing distance onshore. The fraction of valid data from the malfunctioning ADVO was high during the three strong flow events (Fig. 4d).

Velocity spectra indicate energetic wave motions at cyclic frequencies f between approximately 0.05 and 0.5 Hz (Fig. 5a). At higher frequencies, spectra of horizontal and vertical velocity are consistent with isotropic inertial-range turbulence, as described by (6) and (7), because f5/3Pww and (12/21)f5/3(Puu + Pυυ − noise level) are nearly independent of f and nearly equal to each other (Fig. 5b). Cospectra of differences between alongshore and vertical velocities measured by the two ADVOs (Fig. 5c), which illustrate the frequency content of dual-sensor estimates of turbulent Reynolds shear stress based on (5), indicate significant contributions to stress between approximately 0.01 and 1.0 Hz. The spectra and cospectra in Fig. 5 are representative of the first six days of the record, when four ADVs functioned well, waves were unbroken, and flows were weak. Spectral shapes for periods with breaking waves are similar. Cospectra of Δυ and Δw during breaking waves were not computed because of short records caused by intermittent malfunctioning of the offshore ADVO (section 2).

Measurements from the beginning of the record, when both ADVOs and the onshore pair of ADVFs functioned well, permit a comparison of redundant stress estimates. The four single-sensor estimates −ρ0υw = −ρ0 cov(υ, w) from individual ADVs (Fig. 6a) are contaminated by waves, and thus are uncorrelated with each other and vary over a range much larger than the wind and wave forcing during this period (Figs. 3a and 3d). In contrast, stress estimates from the pair of ADVFs and the pair of ADVOs (Fig. 6b) are well correlated (r2 = 0.62), consistent in magnitude (b = 1.0 ± 0.2 at 95% confidence), and much smaller than the single-sensor estimates.

Time series of the terms in (1)–(4) are dominated by a few brief events when strong winds and waves forced energetic flows. Estimates of the left and right sides of (1) (Figs. 7a and 7b) are well correlated (r2 = 0.63), but the turbulent Reynolds stress is approximately half the sum of the wave and wind forcing (b = 0.51 ± 0.03). In (2), dissipation and shear production are well correlated (r2 = 0.70) and consistent in magnitude (b = 1.1 ± 0.1), even though dissipation was large while shear production was small during an event centered on day 270 (Figs. 8a and 8b). Dissipation and shear production are two orders of magnitude smaller than the depth-averaged rate at which the shoaling waves lose energy to breaking (Fig. 8c). Estimates of −ρ0uw obtained from an expression analogous to (5) indicate that the production term −uwu/∂z, which has been neglected in (2), is an order of magnitude smaller than −υwυ/∂z. Estimates of the terms on the right and left sides of (3) (Figs. 9a and 9b) are well correlated (r2 = 0.75), but log-profile estimates of alongshore stress are approximately twice as large as estimates based on (5) (b = 2.2 ± 0.1), indicating a departure from the Prandtl–von Kármán logarithmic velocity profile. A quadratic drag law with a best-fit drag coefficient of cd = (0.71 ± 0.03) × 10−3 (Figs. 9a and 9c) is well correlated with stress estimates based on (5) (r2 = 0.80). Corresponding estimates during periods with unbroken waves and weak flows (υ < 0.2 m s−1) are weakly correlated (r2 = 0.39) and indicate a larger drag coefficient of cd = (1.9 ± 0.2) × 10−3.

Acoustical measurements of bedform geometry on the same isobath as the ADV frame (Hanes and Alymov 2000, submitted to J. Geophys. Res.) indicate short ripples, with heights up to 0.02 m and lengths up to 0.25 m, and long ripples, with heights up to 0.06 m and lengths up to 2 m. The heights and inverse wavenumbers of these bedforms are smaller than the ADV measurement heights, indicating that local flow distortions by bedforms had a negligible effect on the ADV measurements.

The results in Figs. 7–9 did not depend sensitively on the rate at which the malfunctioning ADVO produced valid data (Fig. 4d), because the correlation coefficients and regression slopes are not systematic functions of percent of valid data collected.

4. Discussion

a. Momentum balance

The factor of 2 difference between the left and right sides of the momentum balance (1) (Fig. 7) might be caused by inaccurate estimates of dSxy/dx or −ρ0υω. Inaccurate estimation of τwy is unlikely to be responsible because τwy was not a dominant term (compare Fig. 3a with Fig. 3d) and because of the consistency of wind stress estimates from sonic and mechanical anemometers (section 2). Inaccurate estimates of dSxy/dx might result from use of linear wave theory to relate bottom pressure to Sxy or from the approximate procedure used to resolve uncertainties in sensor orientation (section 2). Estimates of −ρ0υw based on (5) are too small, possibly explaining the observed differences between the left and right sides of (1) if the distance between the two ADVOs was smaller than the correlation scale of the turbulence. To assess this effect, stress estimates based on (5) were computed using all pairs from the four ADVs that functioned during the first-six days of the record, providing spatial separations ranging from 0.6 to 2.3 m. No significant increase in magnitude of stress estimates occurs with increasing sensor separation during this period. However, turbulence correlation scales might have increased during the more energetic events that dominate Fig. 7, because of advection of turbulence by large wave-induced velocities.

The differences between the left and right sides of (1) might also be caused by omitted terms in the alongshore momentum balance, including divergence of a shoreward flux of alongshore momentum by shear waves (Oltman-Shay et al. 1989; Bowen and Holman 1989), an alongshore pressure gradient, or advective acceleration of the hour-averaged flow. Velocity fluctuations at frequencies below the wind wave band contributed negligibly to shoreward fluxes of alongshore momentum at the ADV frame, indicating that shear waves had a small effect on the alongshore momentum balance. The pressure term neglected in (1) is O(ρ0ghη/∂y), where g is gravitational acceleration. To produce dynamically significant values of O(1 Pa) at h = 4.5 m, the alongshore surface slope ∂η/∂y must be O(2 × 10−5). Measurements sufficient to resolve slopes of this magnitude were not obtained. Previous pressure measurements at the same site at alongshore separations of tens of kilometers (Lentz et al. 1999) indicate that peak alongshore surface slopes were an order of magnitude smaller than 2 × 10−5 (S. Lentz 2000, personal communication), but larger gradients might have occurred at smaller scales, for example, because of alongshore variability in wave statistics produced by alongshore-nonuniform bathymetry. A typical advective term neglected in (1) is O(ρ0hυυ/∂y). To produce dynamically significant values of O(1 Pa) at h = 4.5 m during strong flows with υ = O(1) m s−1, ∂υ/∂y must be O(2 × 10−4) s−1, corresponding to differences Δυ of O(0.04) m s−1 at an alongshore separation of 200 m. Velocity measurements from electromagnetic sensors 100 m north and south of the ADV frame indicate Δυ exceeding this value, so that advective acceleration possibly is significant. A quantitative assessment, difficult because of measurement uncertainties, is beyond the scope of this study.

b. Energetics, velocity profile, and drag laws

Figure 8 indicates that a balance between shear production and dissipation controlled the energetics of near-bottom turbulence at the ADV frame and that breaking-induced dissipation associated with the shoreward decrease of wave-induced energy flux did not penetrate to the depth of the ADVs. These observations are similar to results in wall-bounded turbulent shear flows in which shear production balances dissipation near the wall (e.g., Tennekes and Lumley 1972). The observations are inconsistent with the simplest model of surf zone turbulence (Battjes 1975), in which breaking-induced dissipation is assumed to be distributed uniformly over the water depth, and they also are inconsistent with empirical results for locally forced waves in deep water (e.g., Terray et al. 1996), which indicate penetration of breaking-induced turbulence to depths of a few times the significant wave height, which exceeds the water depth in the surf zone. However, the observations are qualitatively consistent with Svendsen's (1987) analysis of laboratory measurements, which indicates that only a small fraction (2%–5%) of the dissipation associated with breaking waves in the surf zone occurs below trough level.

Possible explanations of the factor of 2 differences between the left and right sides of (3) (Fig. 9), indicating departure from the Prandtl–von Kármán velocity profile, include inaccurate estimates of −ρ0υw, discussed in section 4a, and stable stratification owing to temperature, salinity, or suspended sediment (e.g., Monin and Yaglom 1971). When combined with ADP estimates of velocity gradient, estimates of buoyancy frequency N obtained from daily measurements of conductivity, temperature, and depth (CTD) at the end of the pier (Fig. 2) yield gradient Richardson numbers Ri = N2/(∂υ/∂z)2 less than roughly 0.01 during the strong events that dominate in Fig. 9, indicating a negligible effect on the structure of the time-averaged velocity profile (e.g., Businger et al. 1971). A commonly used model of stratification by suspended sediment (e.g., Glenn and Grant 1987) is
i1520-0485-31-8-2403-e11
where u = |υw|1/2 is shear velocity, β is an empirical constant approximately equal to 5 (Hogstrom 1988), and L is the Monin–Obukhov length, defined for stratification by sediments in steady state by
i1520-0485-31-8-2403-e12
where s and ws are specific gravity and settling velocity of the sediments, respectively, and c is time-averaged sediment concentration by volume. With s = 2.65 and ws = 0.02 m s−1, typical of beach sands at Duck (Stauble 1992), (11) and (12) imply that c must be O(4 × 10−5) at the ADVO measurement height z + h ≃ 0.85 m to balance the left and right sides of (3) during strong events. Concentration measurements sufficient to test this computation were not obtained at the ADV frame. A model of the vertical distribution of suspended sediment in turbulent shear flows [Eq. (15) of Taylor and Dyer 1977] suggests that concentrations of this magnitude are unlikely because rapid decay of c with z requires c = O(1) (pure sediment and no water) at z ≃ 0.2 m, which clearly is implausible, to produce c = O(4 × 10−5) at z + h = 0.85 m. However, this calculation is sensitive to the poorly constrained turbulent Prandtl number for sediments, and the model of sediment distribution has not been tested in the surf zone.

The drag coefficient estimated from (4) for unbroken waves [cd = (1.9 ± 0.2) × 10−3] is consistent with a previous nearshore estimate seaward of the surf zone (Feddersen et al. 1998). However, the smaller drag coefficient determined for breaking waves [cd = (0.71 ± 0.03) × 10−3] is smaller than other estimates obtained in the surf zone (Thornton and Guza 1986; Whitford and Thornton 1996) and contradicts studies that produced larger estimates of drag coefficients under breaking waves than under nonbreaking waves (Feddersen et al. 1998; Lentz et al. 1999). A reduced cd under breaking waves is plausible because large wave-induced velocities destroyed bedforms (Hanes and Alymov 2000, submitted to J. Geophys. Res.), and breaking-induced turbulence did not penetrate to the measurement depth (Fig. 8). In addition, stable stratification by suspended sediments may have occurred near the seafloor, increasing ∂υ/∂z and thus υ for a fixed bottom stress (e.g., Taylor and Dyer 1977). Alternatively, the small cd observed here under breaking waves could result from inaccurate estimates of ρ0υw (section 4a). If the true ρ0υw under breaking waves is twice as large as indicated by estimates based on (5), cd would double and the momentum balance (1) would close. However, a doubling of −ρ0υw would cause a factor of 2 more shear production (Fig. 8a) than dissipation (Fig. 8b).

5. Summary and conclusions

Measurements of turbulence, waves, currents, and wind permit examination of 1) an approximate alongshore momentum balance between wind stress, cross-shore gradient of wave-induced radiation stress, and near-bottom turbulent Reynolds stress; 2) an approximate turbulence energy balance, in which dissipation balances the sum of shear production and the depth-averaged rate at which breaking extracts energy from the shoaling wave field; 3) the Prandtl–von Kármán representation of the velocity profile in a wall-bounded shear flow; and 4) a quadratic drag law. The results are dominated by three events when large winds and waves forced strong flows, and the sensors were in the outer part of the surf zone. Estimates of near-bottom turbulent Reynolds shear stress are smaller than the sum of wind and wave forcing by a factor of approximately 2. In the turbulent energy balance shear production balances dissipation, and both are two orders of magnitude smaller than the depth-averaged rate of energy loss by the shoaling wave field, suggesting that breaking-induced turbulence did not extend to the measurement depth. Near-bottom velocity gradients are larger by approximately 50% than indicated by the Prandtl–von Kármán logarithmic velocity law, given estimates of bottom stress. The bottom drag coefficient for unbroken waves is similar to a previous nearshore estimate outside of the surf zone, but the drag coefficient for breaking waves is smaller than values from previous results based on indirect estimates of bottom stress.

The reasons for the imbalances in the momentum equation and the Prandtl–von Kármán velocity profile are not known. However, turbulent Reynolds shear stress was central to these balances, and the technique for estimation of stress is based on the explicit assumption that the spatial scales of the stress-carrying near-bottom motions are smaller than the height above bottom. The present measurements are not sufficient to test this assumption. Determining the spatial scales of the stress-carrying motions in wave-driven nearshore flows is an important question for future research. Other unresolved questions include the adequacy of linear theory to estimate the cross-shore gradient of wave-induced radiation stress in breaking waves, the role of nonlinear advective terms and pressure gradient in the alongshore momentum balance, the effect of bedforms and suspended sediments on nearshore flows, and the vertical structure of dissipation in the surf zone.

Acknowledgments

Staff from the Field Research Facility, Duck, NC, and the Center for Coastal Studies, Scripps Institution of Oceanography, deployed, maintained, and recovered the instruments in harsh surf zone conditions. R. T. Guza, T. H. C. Herbers, B. Raubenheimer, and W. C. O'Reilly helped design and manage the field experiment and provided high-quality processed measurements of wave statistics and currents. P. Howd planned, obtained, and processed the ADP measurements. J. Fredericks, G. Voulgaris, and A. Williams obtained the ADV measurements, and J. Fredericks processed the ADV data. J. Edson obtained and processed the wind measurements. S. Lentz and F. Feddersen provided useful comments on the manuscript. Funding was provided by the Office of Naval Research, the National Science Foundation, the Mellon Foundation, and the Woods Hole Oceanographic Institution's Rinehart Coastal Research Center.

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APPENDIX

Model of High-Frequency Turbulent Velocity Spectra

The purpose of the appendix is to derive the models (6) and (7) for the high-frequency spectra of near-bottom velocities measured by a point sensor past which inertial-range turbulence is advected by a mean current and wave-induced velocities. It is convenient to use indicial notation, in which the coordinates are (x1, x2, x3), where x3 is vertical, and the corresponding turbulent velocity vector is (u1, u2, u3). The starting point is Eq. (A11) of Lumley and Terray (1983):
i1520-0485-31-8-2403-ea1
Here ω is radian frequency, Pij is the measured turbulence spectrum, defined so that +∞−∞ Pij(ω) = uiuj, τ is a dummy variable of integration, ϕij is the spectrum tensor of the turbulence (e.g., Batchelor 1967), k is the wavenumber vector, U is the mean velocity vector, and σ21, σ22, and σ23 are the nonzero elements of the covariance tensor of the wave-induced velocity vector, which has been diagonalized. Equation (A1) is an asymptotic result for frequencies large in comparison with the dominant wave frequency. Of particular interest are P11(ω) + P22(ω) and P33(ω), which are invariant under coordinate rotations about the x3 axis.
Several idealizations simplify the analysis. The turbulence is assumed to be homogeneous and isotropic:
i1520-0485-31-8-2403-ea2
and to have a Kolmogorov spectrum:
Ekαϵ2/3k−5/3
(e.g., Batchelor 1967). Here E(k) is the isotropic energy spectrum, k is the magnitude of k, δij is the Kronecker delta, α is the empirical Kolmogorov constant, and ϵ is the dissipation rate. In addition, attention is restricted to cases with σ3 = 0 and U3 = 0, which is appropriate for near-bottom applications, and to cases with waves that are narrowbanded in direction so that σ2 = 0, where, without loss of generality, x1 is defined to be the direction of wave propagation. Substitution of (A2) and (A3) into (A1), and use of standard results to evaluate the τ integral (e.g., Gradshteyn and Ryzhik 1965), yields
i1520-0485-31-8-2403-ea4
where V cos(θ) = U1 and V sin(θ) = U2, with V ≥ 0.
For the special case i = j = 3, the k3 integral in (A4) can be evaluated in terms of gamma functions (e.g., Abramowitz and Stegun 1972), leading to
i1520-0485-31-8-2403-ea5
For the contraction Pii, the k3 integral similarly can be evaluated in terms of gamma functions, and it follows that
i1520-0485-31-8-2403-ea6
so that, once P33 has been determined, P11 + P22 is also known. Therefore attention is restricted to P33.
Two sets of transformations of (A5) are necessary. The first is substitution of y = k2/k1, with special attention to the behavior near k1 = 0 and near k1 → ±∞, followed by substitution of x = ω/(k1V), which leads to
i1520-0485-31-8-2403-ea7
where primes have been omitted.
Equation (A8) can be reduced to a single integral by considering two methods of obtaining the pure current limit, σ1 → 0. In this limit, P33 does not depend on θ, so θ can be set to zero in (A7). The y integral in (A7) then can be evaluated in terms of gamma functions. In the x integral, the exponential function behaves like a Dirac delta function centered at x = 1 in the limit σ1 → 0, so x can be set to unity except in the exponential, which permits straightforward evaluation. The result of these operations is
i1520-0485-31-8-2403-ea9
which is consistent with results for steady flows (Batchelor 1967). Alternatively, as σ1 → 0 in (A8), the exponential acts like a delta function centered at y = −cot(θ) so that y can be replaced by −cot(θ) in all terms except the exponential. The y integral can then be evaluated, yielding
i1520-0485-31-8-2403-ea10
Equations (A9) and (A10) must be equal, so that
i1520-0485-31-8-2403-ea11
Substitution of y = cot(θ) gives
i1520-0485-31-8-2403-ea12
which is an evaluation of the x integral in (A8). Substitution of (A12) into (A8) and use of a change of variables leads to (7), where
i1520-0485-31-8-2403-ea13
an integral that easily is evaluated numerically. Use of (A6) then gives (6).

Fig. 1.
Fig. 1.

Array of near-bottom acoustic Doppler current meters deployed in about 4.5-m water depth approximately 300 m from the shoreline. ADVF and ADVO are SonTek field and ocean probes, respectively

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 2.
Fig. 2.

Locations of instruments (labeled) and contours of water depth (in m below mean sea level every 0.5 m) for yearday 226. Each compact array (CA6 and CA7) contained six accurately (±0.5 m) surveyed bottom-mounted pressure sensors (small filled circles) and one current meter located about 0.5 m above the bottom near the center of the array (not shown) (Herbers et al. 2000, submitted to J. Phys. Oceanogr.). The shoreline location was centered approximately at cross-shore location = 125 m, with ≃ ±10 m cross-shore fluctuations caused by the 1-m tidal range. The bathymetry seaward of about 3.5-m depth did not change significantly during the experiment

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 3.
Fig. 3.

(a) Alongshore wind stress, (b) significant wave height, (c) cross-shore gradient of wave-induced energy flux, and (d) cross-shore gradient of wave-induced radiation stress vs time

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 4.
Fig. 4.

(a) Cross-shore velocity (negative is offshore-directed flow), (b) alongshore velocity (positive is flow toward the south), (c) cross-shore gradient of alongshore velocity, and (d) percent of valid data from the malfunctioning ADVO vs time

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 5.
Fig. 5.

Energy density spectra from (a) velocity time series and (b) modified according to (6) and (7). Solid curves are Puu + Pυυ and dashed curves are Pww. (c) Integral of cospectrum of velocity differences vs frequency. Data are from 25-min-long ADVO records obtained at 12:00 (EST) on yearday 236. The burst-averaged cross-shore and alongshore currents were −0.02 and 0.10 m s−1, respectively, and the significant wave height was 1.0 m

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 6.
Fig. 6.

Estimates of near-bottom stress using (a) single and (b) dual sensors vs time. (b) Estimates from the pair of ADVOs and ADVFs are shown as solid and dashed curves, respectively

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 7.
Fig. 7.

(a) Sum of wind and wave forcing and (b) near-bottom turbulent Reynolds shear stress vs time

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 8.
Fig. 8.

(a) Shear production of turbulent kinetic energy, (b) dissipation of turbulent kinetic energy, and (c) depth-averaged rate of energy extraction from the shoaling wave field vs time. The vertical scale in (c) is different than in (a) and (b)

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

Fig. 9.
Fig. 9.

(a) Covariance, (b) log profile, and (c) drag law estimates of turbulent Reynolds shear stress vs time

Citation: Journal of Physical Oceanography 31, 8; 10.1175/1520-0485(2001)031<2403:TMITSZ>2.0.CO;2

*

Woods Hole Oceanographic Institution Contribution Number 10275.

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