Litcius/Paper detail

Beach Slopes From Satellite‐Derived Shorelines

Kilian Vos, Mitchell D. Harley, Kristen D. Splinter, Andrew Walker, Ian L. Turner

2020Geophysical Research Letters157 citationsDOI

Abstract

Abstract The steepness of the beach face is a fundamental parameter for coastal morphodynamic research. Despite its importance, it remains extremely difficult to obtain reliable estimates of the beach‐face slope over large spatial scales (thousands of km of coastline). In this letter, a novel approach to estimate this slope from time series of satellite‐derived shoreline positions is presented. This new technique uses a frequency domain analysis to find the optimum slope that minimizes high‐frequency tidal fluctuations relative to lower‐frequency erosion/accretion signals. A detailed assessment of this new approach at eight locations spanning a range of tidal regimes, wave climates, and sediment grain sizes shows strong agreement ( R 2 = 0.93) with field measurements. The automated technique is then applied across thousands of beaches in eastern Australia and California, USA, revealing similar regional‐scale distributions along these two contrasting coastlines and highlights the potential for new global‐scale insight to beach‐face slope spatial distribution, variability, and trends.

Topics & Concepts

ShoreGeologyAccretion (finance)Scale (ratio)Range (aeronautics)SatelliteErosionCoastal erosionTemporal scalesTidal rangeBeach morphodynamicsSedimentSediment transportGeomorphologyOceanographyGeographyEstuaryCartographyAstrophysicsAerospace engineeringEcologyComposite materialBiologyEngineeringMaterials sciencePhysicsCoastal and Marine DynamicsCoastal wetland ecosystem dynamicsOcean Waves and Remote Sensing