Determining suspended sand size and concentration from multifrequency acoustic backscatter

Crawford, Anna; Hay, Alex E.

doi:10.1121/1.407237

Cited by 112 publications

(72 citation statements)

References 2 publications

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“…Methods to compute c directly from backscattered pressure, accounting for signal loss due to water absorption and sediment scattering (e.g. Betteridge et al [2]; Thorne and Hanes [4]; Crawford and Hay [5]) are difficult to apply for single-frequency sensors when the sediment is inhomogeneous, consisting of a mixture of sand and wash load, and they usually further require an independent estimate of c at some point within the water column. The latter could not be achieved for the deployments at Vejers because the tripod settled some 15 cm into the bed upon deployment and an OBS-3 optical backscatter sensor mounted at a nominal elevation of 0.05 m above the bed was below bed level, or interfering with the bed during the deployment periods.…”

Section: Methodsmentioning

confidence: 99%

Measuring suspended sand transport using a pulse-coherent acoustic Doppler profiler

Aagaard

Greenwood

2009

WIT Transactions on Ecology and the Environment

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A simple method to derive sediment transport rates in the nearshore from PulseCoherent Acoustic Doppler Profilers (PC-ADP) is described. Measured sediment concentration profiles are compared with theoretically estimated concentration profiles and exhibit good agreement. Cross-shore and longshore sediment transport rates obtained during 5-6 week long deployments on the lower shoreface in 6-8 m water depth are compared with predictions from an energetics transport model. The two estimates agree to within 20% in the longshore direction while the cumulated cross-shore wave-dominated transport component is trending significantly less offshore for the measurements than for the model predictions. The measurements indicate that significant onshore sediment transport from the lower to the upper shoreface only occurs when waves are close to breaking.

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Section: Methodsmentioning

confidence: 99%

Measuring suspended sand transport using a pulse-coherent acoustic Doppler profiler

Aagaard

Greenwood

2009

WIT Transactions on Ecology and the Environment

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“…Here, α s was calculated for each experiment using Equation (5). This approach was proposed by Crawford and Hay [10] as a modification of Urick's (1948) Equation [52]:…”

Section: Instrumentation and Theoretical Backgroundmentioning

confidence: 99%

“…In some cases, the spatial variation in concentration might also be quantifiable. Methods employing acoustic signals tend to be less problematic logistically, as optical sensors are typically much more sensitive to biofouling in natural environments [10][11][12][13]. Multi-frequency acoustic sensors also have the potential to provide information on the size distribution of the suspended sediment.…”

Section: Introductionmentioning

confidence: 99%

Sediment Size Effects in Acoustic Doppler Velocimeter-Derived Estimates of Suspended Sediment Concentration

Öztürk

2017

Water

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Backscatter output from a 10 MHz acoustic Doppler velocimeter (ADV) was used to quantify suspended sediment concentrations in a laboratory setting using sand-sized particles. The experiments included (a) well-sorted sand samples ranging in size from 0.112 to 0.420 mm, obtained by the sieving of construction sand, (b) different, known mixtures of these well-sorted fractions, and (c) sieved natural beach sand with median sizes ranging from 0.112 to 0.325 mm. The tested concentrations ranged from 25 to 3000 mg·L −1 . The backscatter output was empirically related to concentration and sediment size, and when non-dimensionalized by acoustic wavelength, a dimensionless sediment size gradation coefficient. Size-dependent upper and lower bounds on measurable concentrations were also established empirically. The range of measurable conditions is broad enough to make the approach useful for sand sizes and concentrations commonly encountered in nature. A new method is proposed to determine concentrations in cases of mixed-size sediment suspensions when only calibration data for well-sorted constituent sands are available. This approach could potentially allow better estimates when the suspended load is derived from but is not fully representative of the bed material, and when the size characteristics of the suspended material are varying in time over the period of interest. Differences in results between the construction and beach sands suggest that sediment shape may also need to be considered, and point to the importance of calibrating to sediments encountered at the site of interest.

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“…The optical and acoustical techniques developed by Hay and Sheng (1992) and Crawford and Hay (1993) are capable of estimating vertical profiles of sediment concentration and mean grain size simultaneously with much higher temporal and spatial resolutions than the pumping, suction, and trapping techniques. Application of the promising acoustic (Hay and Sheng 1992) and laser (Agrawal et al 1996) techniques inside the surf zone is currently limited by several factors, including: (1) harsh environmental conditions caused by high wave energy; (2) significant amount of air bubbles in the water column; (3) large sediment particles in suspension; (4) difficulty in obtaining near-bed (e.g., Ͻ 5 cm) measurements; and (5) high cost.…”

Section: Introductionmentioning

confidence: 99%

“…Information on the cross-shore and vertical distributions of grain size also enters engineering applications, such as determining compatibility of beach nourishment material and designing of coastal structures to hold sand. Although there have been a large number of studies on the concentration of suspended sediment in the nearshore zone (e.g., Fairchild 1977;Kana 1979;Nielsen 1984;Zampol and Inman 1989;Zampol and Waldorf 1989;Greenwood et al 1991;Barkaszi and Dally 1992;Hay and Sheng 1992;Crawford and Hay 1993), only a few studies have addressed the vertical grain-size distribution of the suspended sediment (Kana 1979;Kennedy et al 1981;Kraus et al 1988;Hay and Sheng 1992), and these studies were conducted on beaches composed of fairly well-sorted fine sands with little cross-shore variation in either mean grain size or grain-size distribution.…”

Section: Introductionmentioning

confidence: 99%

Cross-shore distribution of sediment texture under breaking waves along low-wave-energy coasts

Wang

Davis

Kraus

1998

Journal of Sedimentary Research

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Sediment samples were collected with streamer traps at different elevations in the water column and across the surf zone. Beach profiles and breaking waves were measured together with the sediment sampling. The experiments were conducted on beaches with various sediment composition ranging from well-sorted fine sand to poorly sorted gravel and shell debris. The cross-shore variation of sediment mean grain size ranged from less than 1 to significant variation of up to 3.5 . The resultant database contains 99 vertical grainsize profiles, composed of 99 bottom samples and 552 trap samples taken throughout the water column and at 29 different locations along the southeast coast of the United States and the Gulf coast of Florida.A homogeneous vertical profile of mean grain size and grain-size distribution pattern was found on most of the beaches with a wide range of sediment sizes. The homogeneous vertical profile, representing 92% of the measurements, was found on all morphological features: swash zone, breaker line, mid-surf zone, trough, and bar. A homogeneous distribution indicates that the vertical mixing mechanism in the water column of the surf zone is independent of sediment size ranging from fine sand to fine pebbles. Bottom sediment, represented by an 8-cm core sample, was generally coarser than the sediment trapped in the water column.

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Determining suspended sand size and concentration from multifrequency acoustic backscatter

Cited by 112 publications

References 2 publications

Measuring suspended sand transport using a pulse-coherent acoustic Doppler profiler

Measuring suspended sand transport using a pulse-coherent acoustic Doppler profiler

Sediment Size Effects in Acoustic Doppler Velocimeter-Derived Estimates of Suspended Sediment Concentration

Cross-shore distribution of sediment texture under breaking waves along low-wave-energy coasts

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