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Nearshore Waves and Littoral Drift Along a Micro-Tidal Wave-Dominated Coast Having Comparable Wind-Sea and Swell Energy

Jesbin George, V. Sanil Kumar, R. Gowthaman, Jai Singh

2020Journal of Marine Science and Engineering20 citationsDOIOpen Access PDF

Abstract

The nearshore wave characteristics and variations in littoral drift (longshore sediment transport; LST) are estimated based on different approaches for four years along the Vengurla coast, with comparable wind-sea and swell energy assessed. The waverider buoy-measured data at 15 m water depth is utilized as the input wave parameters along with the reanalysis model data, and the numerical wave model Delft-3D is used for estimating the nearshore wave parameters. The relative contribution of wind-seas and swells on LST rates are specifically examined. The clear prevalence of west-southwest waves implies the prevalence of south to north longshore sediment transport with net transport varying from 0.19–0.37 × 105 m3/yr. LST is strongly dependent on the breaker angle and a small change in the wave direction substantially alters the LST, and hence reanalysis/model data with coarse resolutions produce large errors (~38%) in the LST estimate. The annual gross LST rate based on integral wave parameters is only 58% considering the wind-seas and swells separately, since the wind-sea energy is comparable to swell energy, and the direction of these two systems differs significantly.

Topics & Concepts

SwellBuoyLongshore driftWave modelWave heightWind waveGeologyShoaling and schoolingSignificant wave heightLittoral zoneEnvironmental scienceSediment transportWind speedMeteorologyOceanographyClimatologySedimentGeographyGeomorphologyCoastal and Marine DynamicsOcean Waves and Remote SensingCoastal wetland ecosystem dynamics
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