High-resolution, large-scale laboratory measurements of a sandy beach and dynamic cobble berm revetment-Reference-Cited by-同舟云学术

High-resolution, large-scale laboratory measurements of a sandy beach and dynamic cobble berm revetment

Published:2021-01-20 Issue:1 Volume:8 Page:
ISSN:2052-4463
Container-title:Scientific Data
language:en
Short-container-title:Sci Data

Author:

Blenkinsopp Chris E.^ORCID,Bayle Paul M.,Conley Daniel C.^ORCID,Masselink Gerd,Gulson Emily,Kelly Isabel,Almar Rafael^ORCID,Turner Ian L.^ORCID,Baldock Tom E.,Beuzen Tomas,McCall Robert T.,Rijper Huub,Reniers Ad,Troch Peter,Gallach-Sanchez David^ORCID,Hunter Alan J.,Bryan Oscar,Hennessey Gwyn,Ganderton Peter,Tissier Marion,Kudella Matthias,Schimmels Stefan^ORCID

Abstract

AbstractHigh quality laboratory measurements of nearshore waves and morphology change at, or near prototype-scale are essential to support new understanding of coastal processes and enable the development and validation of predictive models. The DynaRev experiment was completed at the GWK large wave flume over 8 weeks during 2017 to investigate the response of a sandy beach to water level rise and varying wave conditions with and without a dynamic cobble berm revetment, as well as the resilience of the revetment itself. A large array of instrumentation was used throughout the experiment to capture: (1) wave transformation from intermediate water depths to the runup limit at high spatio-temporal resolution, (2) beach profile change including wave-by-wave changes in the swash zone, (3) detailed hydro and morphodynamic measurements around a developing and a translating sandbar.

Funder

EC | Horizon 2020 Framework Programme

Deltares Strategic Research Program

RCUK | Engineering and Physical Sciences Research Council

Publisher

Springer Science and Business Media LLC

Subject

Library and Information Sciences,Statistics, Probability and Uncertainty,Computer Science Applications,Education,Information Systems,Statistics and Probability

Link

http://www.nature.com/articles/s41597-021-00805-1.pdf

Reference25 articles.

1. Almeida, L. P., Masselink, G., McCall, R. & Russell, P. E. Storm overwash of a gravel barrier: Field measurements and XBeach-G modelling. Coast. Eng. 120, 22–35 (2017).

2. Briganti, R., Dodd, N., Incelli, G. & Kikkert, G. Numerical modelling of the flow and bed evolution of a single bore-driven swash event on a coarse sand beach. Coast. Eng. 142, 62–76 (2018).

3. Masselink, G. et al. Large-scale Barrier Dynamics Experiment II (BARDEX II): Experimental design, instrumentation, test program, and data set. Coast. Eng. 113, 3–18 (2016).

4. Eichentopf, S., van der Zanden, J., Cáceres, I., Baldock, T. E. & Alsina, J. M. Influence of storm sequencing on breaker bar and shoreline evolution in large-scale experiments. Coast. Eng. 157, 103659 (2020).

5. Allan, J. C. & Komar, P. Environmentally compatible berm and artificial dune for shore protection. Shore and Beach 721, 9–16 (2004).

Cited by 8 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Practical modelling of sand transport and beach profile evolution in the swash zone;Coastal Engineering;2024-08

2. Modelling beaches morphodynamic by Hadamard sensitivity analysis;Ocean Modelling;2024-06

3. Repeatability of beach morphology change under identical wave forcing;Coastal Engineering;2024-04

4. Remotely sensed short-crested breaking waves in a laboratory directional wave basin;Coastal Engineering;2023-08

5. Comparison of dynamic cobble berm revetments with differing gravel characteristics;Coastal Engineering;2023-08