Novel sediment sampling method provides new insights into vertical grain size variability due to marine and aeolian beach processes

Journal Article (2022)
Author(s)

C. van IJzendoorn (TU Delft - Coastal Engineering)

E.C. Hallin (TU Delft - Coastal Engineering, Lund University)

Nicholas Cohn (U.S. Army Engineer Research and Development Center)

Ad J.H.M. Reniers (TU Delft - Environmental Fluid Mechanics)

S. Vries (TU Delft - Coastal Engineering)

Research Group
Coastal Engineering
Copyright
© 2022 Christa van IJzendoorn, E.C. Hallin, Nicholas Cohn, A.J.H.M. Reniers, S. de Vries
DOI related publication
https://doi.org/10.1002/esp.5518
More Info
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Publication Year
2022
Language
English
Copyright
© 2022 Christa van IJzendoorn, E.C. Hallin, Nicholas Cohn, A.J.H.M. Reniers, S. de Vries
Related content
Research Group
Coastal Engineering
Issue number
4
Volume number
48
Pages (from-to)
782-800
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Abstract

In sandy beach systems, the aeolian sediment transport can be governed by the vertical structure of the sediment layers at the bed surface. Here, data collected with a newly developed sand scraper is presented to determine high-resolution vertical grain size variability and how it is affected by marine and aeolian processes. Sediment samples at up to 2 mm vertical resolution down to 50 mm depth were collected at three beaches: Waldport (Oregon, USA), Noordwijk (the Netherlands) and Duck (North Carolina, USA). The results revealed that the grain size in individual layers can differ considerably from the median grain size of the total sample. The most distinct temporal variability occurred due to marine processes that resulted in significant morphological changes in the intertidal zone. The marine processes during high water resulted both in fining and coarsening of the surface sediment. Especially near the upper limit of wave runup, the formation of a veneer of coarse sediment was observed. Although the expected coarsening of the near-surface grain size during aeolian transport events was observed at times, the opposite trend also occurred. The latter could be explained by the formation and propagation of aeolian bedforms within the intertidal zone locally resulting in sediment fining at the bed surface. The presented data lays the basis for future sediment sampling strategies and sediment transport models that investigate the feedbacks between marine and aeolian transport, and the vertical variability of the grain size distribution.