Wind-blown sand on beaches: an evaluation of models
Identifieur interne : 000E63 ( Main/Exploration ); précédent : 000E62; suivant : 000E64Wind-blown sand on beaches: an evaluation of models
Auteurs : Douglas J. Sherman [États-Unis] ; Derek W. T. Jackson [Irlande (pays)] ; Steven L. Namikas [États-Unis] ; Jinkang Wang [États-Unis]Source :
- Geomorphology [ 0169-555X ] ; 1998.
English descriptors
- Teeft :
- Aeolian, Aeolian sand transport, Aeolian sediment transport, Aeolian system, Aeolian transport, Anemometer, Anemometer towers, April, Army corps, Bagnold, Bagnold kawamura zingg kadib lettau, California hydraulics engineering laboratory report, Coastal, Coastal dunes, Confidence level, Confidence limits, Correction factors, Corrections, Cylindrical traps, Data acquisition period, Data points, Data sets, Desert sand, Different models, Driest climate, Dune, Dune migration, Earth surf, Elevation, Empirical constants, Empirical data, Environmental studies, Experimental design, Field data, Field experiments, Field methods, Foredune, Foredune system, Foreshore, Geomorphology, Grain diameter, Grain size, Grain size data, Grain size estimates, Gravitational acceleration, Highest rates, Horikawa, Hydraulics, Hydraulics conf, Inch experiments, Instrument line, Iowa city, Kadib, Kadib model, Kawamura, Kawamura model, Laboratory facilities, Lettau, Lettau model, Micrometeorological field studies, Moisture, Moisture content, Moisture contents, Nordstrom, Pore spaces, Predictive competence, Proc, Processes landforms, Regression statistics, Sampling duration, Sand movement, Sand surface, Sand transport, Sand transport rate, Sarre, Sediment, Sediment balance, Sediment moisture content, Sediment systems, Sediment transport, Sedimentary material, Shear velocities, Shear velocity, Slope correction, Slope effects, Solid line, Strong correspondence, Study site, Such models, Surface moisture content, Surface sediments, Surface slope, Third rock, Threshold conditions, Threshold shear velocity, Tower, Tower location, Transport, Transport models, Transport predictions, Transport processes, Transport surface, Transport system, University college, Velocity profile, Velocity profiles, Vertical velocity profiles, Wind direction, Wind field, Wind measurements, Wind speed, Wind speeds, Wind tunnel studies, Wind velocity, Zingg, Zingg model, Zingg models.
Abstract
Five models for predicting rates of aeolian sand transport were evaluated using empirical data obtained from field experiments conducted in April, 1994 at a beach on Inch Spit, Co. Kerry, Republic of Ireland. Measurements were made of vertical wind profiles (to derive shear velocity estimates), beach slope, and rates of sand transport. Sediment samples were taken to assess characteristics of grain size and surface moisture content. Estimates of threshold shear velocity were derived using grain size data. After parsing the field data on the basis of the quality of shear velocity estimation and the occurrence of blowing sand, 51 data sets describing rates of sand transport and environmental conditions were retained. Mean grain diameter was 0.17 mm. Surface slopes ranged from 0.02 on the foreshore to about 0.11 near the dune toe. Mean shear velocities ranged from 0.23 m s−1 (just above the observed transport threshold) to 0.65 m s−1. Rates of transport ranged from 0.02 kg m−1 h−1 to more than 80 kg m−1 h−1. These data were used as input to the models of Bagnold [Bagnold, R.A., 1936. The Movement of Desert Sand. Proc. R. Soc. London, A157, 594–620], Kawamura [Kawamura, R., 1951. Study of Sand Movement by Wind. Translated (1965) as University of California Hydraulics Engineering Laboratory Report HEL 2–8, Berkeley], Zingg [Zingg, A.W., 1953. Wind tunnel studies of the movement of sedimentary material. Proc. 5th Hydraulics Conf. Bull. 34, Iowa City, Inst. of Hydraulics, pp. 111–135], Kadib [Kadib, A.A., 1965. A function for sand movement by wind. University of California Hydraulics Engineering Laboratory Report HEL 2–8, Berkeley], and Lettau and Lettau [Lettau, K. and Lettau, H., 1977. Experimental and Micrometeorological Field Studies of Dune Migration. In: K. Lettau and H. Lettau (Eds.), Exploring the World's Driest Climate. University of Wisconsin-Madison, IES Report 101, pp. 110–147]. Correction factors to adjust predictions of the rate of transport to account for the effects of slope and moisture content were calculated using the models of Bagnold [Bagnold, R.A., 1973. The nature of saltation and ‘bed-load’ transport in water. Proc. R. Soc. London, Ser. A, 332, 473–504] and Belly [Belly, P.-Y., 1964. Sand movement by wind. U.S. Army Corps Eng. CERC. Tech. Mem. 1, Washington D.C., 38 pp.], respectively. None of the models was able to produce a strong correspondence between measured and predicted rates of transport. Best results were obtained using the Bagnold and Zingg models, and the Kadib model was the least viable of this group. The influence of sediment moisture content appeared to be the critical factor in degrading model viability. Overall, none of the models is adequate for general applications to coastal-aeolian environments where moisture content complications tend to override the predictive competence of the simple transport formulations.
Url:
DOI: 10.1016/S0169-555X(97)00062-7
Affiliations:
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Namikas</name><affiliation wicri:level="4"><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Geography, University of Southern California, Los Angeles, CA 90089-0225</wicri:regionArea><orgName type="university">Université de Californie du Sud</orgName><placeName><settlement type="city">Los Angeles</settlement><region type="state">Californie</region></placeName></affiliation></author><author><name sortKey="Wang, Jinkang" sort="Wang, Jinkang" uniqKey="Wang J" first="Jinkang" last="Wang">Jinkang Wang</name><affiliation wicri:level="4"><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Geography, University of Southern California, Los Angeles, CA 90089-0225</wicri:regionArea><orgName type="university">Université de Californie du Sud</orgName><placeName><settlement type="city">Los Angeles</settlement><region type="state">Californie</region></placeName></affiliation></author></analytic><monogr></monogr><series><title level="j">Geomorphology</title><title level="j" type="abbrev">GEOMOR</title><idno type="ISSN">0169-555X</idno><imprint><publisher>ELSEVIER</publisher><date type="published" when="1998">1998</date><biblScope unit="volume">22</biblScope><biblScope unit="issue">2</biblScope><biblScope unit="page" from="113">113</biblScope><biblScope unit="page" to="133">133</biblScope></imprint><idno type="ISSN">0169-555X</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0169-555X</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="Teeft" xml:lang="en"><term>Aeolian</term><term>Aeolian sand transport</term><term>Aeolian sediment transport</term><term>Aeolian system</term><term>Aeolian transport</term><term>Anemometer</term><term>Anemometer towers</term><term>April</term><term>Army corps</term><term>Bagnold</term><term>Bagnold kawamura zingg kadib lettau</term><term>California hydraulics engineering laboratory report</term><term>Coastal</term><term>Coastal dunes</term><term>Confidence level</term><term>Confidence limits</term><term>Correction factors</term><term>Corrections</term><term>Cylindrical traps</term><term>Data acquisition period</term><term>Data points</term><term>Data sets</term><term>Desert sand</term><term>Different models</term><term>Driest climate</term><term>Dune</term><term>Dune migration</term><term>Earth surf</term><term>Elevation</term><term>Empirical constants</term><term>Empirical data</term><term>Environmental studies</term><term>Experimental design</term><term>Field data</term><term>Field experiments</term><term>Field methods</term><term>Foredune</term><term>Foredune system</term><term>Foreshore</term><term>Geomorphology</term><term>Grain diameter</term><term>Grain size</term><term>Grain size data</term><term>Grain size estimates</term><term>Gravitational acceleration</term><term>Highest rates</term><term>Horikawa</term><term>Hydraulics</term><term>Hydraulics conf</term><term>Inch experiments</term><term>Instrument line</term><term>Iowa city</term><term>Kadib</term><term>Kadib model</term><term>Kawamura</term><term>Kawamura model</term><term>Laboratory facilities</term><term>Lettau</term><term>Lettau model</term><term>Micrometeorological field studies</term><term>Moisture</term><term>Moisture content</term><term>Moisture contents</term><term>Nordstrom</term><term>Pore spaces</term><term>Predictive competence</term><term>Proc</term><term>Processes landforms</term><term>Regression statistics</term><term>Sampling duration</term><term>Sand movement</term><term>Sand surface</term><term>Sand transport</term><term>Sand transport rate</term><term>Sarre</term><term>Sediment</term><term>Sediment balance</term><term>Sediment moisture content</term><term>Sediment systems</term><term>Sediment transport</term><term>Sedimentary material</term><term>Shear velocities</term><term>Shear velocity</term><term>Slope correction</term><term>Slope effects</term><term>Solid line</term><term>Strong correspondence</term><term>Study site</term><term>Such models</term><term>Surface moisture content</term><term>Surface sediments</term><term>Surface slope</term><term>Third rock</term><term>Threshold conditions</term><term>Threshold shear velocity</term><term>Tower</term><term>Tower location</term><term>Transport</term><term>Transport models</term><term>Transport predictions</term><term>Transport processes</term><term>Transport surface</term><term>Transport system</term><term>University college</term><term>Velocity profile</term><term>Velocity profiles</term><term>Vertical velocity profiles</term><term>Wind direction</term><term>Wind field</term><term>Wind measurements</term><term>Wind speed</term><term>Wind speeds</term><term>Wind tunnel studies</term><term>Wind velocity</term><term>Zingg</term><term>Zingg model</term><term>Zingg models</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Five models for predicting rates of aeolian sand transport were evaluated using empirical data obtained from field experiments conducted in April, 1994 at a beach on Inch Spit, Co. Kerry, Republic of Ireland. Measurements were made of vertical wind profiles (to derive shear velocity estimates), beach slope, and rates of sand transport. Sediment samples were taken to assess characteristics of grain size and surface moisture content. Estimates of threshold shear velocity were derived using grain size data. After parsing the field data on the basis of the quality of shear velocity estimation and the occurrence of blowing sand, 51 data sets describing rates of sand transport and environmental conditions were retained. Mean grain diameter was 0.17 mm. Surface slopes ranged from 0.02 on the foreshore to about 0.11 near the dune toe. Mean shear velocities ranged from 0.23 m s−1 (just above the observed transport threshold) to 0.65 m s−1. Rates of transport ranged from 0.02 kg m−1 h−1 to more than 80 kg m−1 h−1. These data were used as input to the models of Bagnold [Bagnold, R.A., 1936. The Movement of Desert Sand. Proc. R. Soc. London, A157, 594–620], Kawamura [Kawamura, R., 1951. Study of Sand Movement by Wind. Translated (1965) as University of California Hydraulics Engineering Laboratory Report HEL 2–8, Berkeley], Zingg [Zingg, A.W., 1953. Wind tunnel studies of the movement of sedimentary material. Proc. 5th Hydraulics Conf. Bull. 34, Iowa City, Inst. of Hydraulics, pp. 111–135], Kadib [Kadib, A.A., 1965. A function for sand movement by wind. University of California Hydraulics Engineering Laboratory Report HEL 2–8, Berkeley], and Lettau and Lettau [Lettau, K. and Lettau, H., 1977. Experimental and Micrometeorological Field Studies of Dune Migration. In: K. Lettau and H. Lettau (Eds.), Exploring the World's Driest Climate. University of Wisconsin-Madison, IES Report 101, pp. 110–147]. Correction factors to adjust predictions of the rate of transport to account for the effects of slope and moisture content were calculated using the models of Bagnold [Bagnold, R.A., 1973. The nature of saltation and ‘bed-load’ transport in water. Proc. R. Soc. London, Ser. A, 332, 473–504] and Belly [Belly, P.-Y., 1964. Sand movement by wind. U.S. Army Corps Eng. CERC. Tech. Mem. 1, Washington D.C., 38 pp.], respectively. None of the models was able to produce a strong correspondence between measured and predicted rates of transport. Best results were obtained using the Bagnold and Zingg models, and the Kadib model was the least viable of this group. The influence of sediment moisture content appeared to be the critical factor in degrading model viability. Overall, none of the models is adequate for general applications to coastal-aeolian environments where moisture content complications tend to override the predictive competence of the simple transport formulations.</div></front></TEI><affiliations><list><country><li>Irlande (pays)</li><li>États-Unis</li></country><region><li>Californie</li></region><settlement><li>Los Angeles</li></settlement><orgName><li>Université de Californie du Sud</li></orgName></list><tree><country name="États-Unis"><noRegion><name sortKey="Sherman, Douglas J" sort="Sherman, Douglas J" uniqKey="Sherman D" first="Douglas J." last="Sherman">Douglas J. Sherman</name></noRegion><name sortKey="Namikas, Steven L" sort="Namikas, Steven L" uniqKey="Namikas S" first="Steven L." last="Namikas">Steven L. Namikas</name><name sortKey="Sherman, Douglas J" sort="Sherman, Douglas J" uniqKey="Sherman D" first="Douglas J." last="Sherman">Douglas J. Sherman</name><name sortKey="Wang, Jinkang" sort="Wang, Jinkang" uniqKey="Wang J" first="Jinkang" last="Wang">Jinkang Wang</name></country><country name="Irlande (pays)"><noRegion><name sortKey="Jackson, Derek W T" sort="Jackson, Derek W T" uniqKey="Jackson D" first="Derek W. T." last="Jackson">Derek W. T. Jackson</name></noRegion></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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