Resilient Solutions for Coastal, Urban, Estuarine and Riverine Environments

Informations projet

RESCUER

N° de convention de subvention: 101119437

DOI

10.3030/101119437

Date de signature de la CE 5 Juillet 2023

Date de début 1 Février 2024

Date de fin 31 Janvier 2028

Financé au titre de

Marie Skłodowska-Curie Actions (MSCA)

Coût total

Aucune donnée

Contribution de l’UE

€ 2 752 149,60

Coordonné par

UNIVERSITETET I BERGEN
Norway

CORDIS fournit des liens vers les livrables publics et les publications des projets HORIZON.

Les liens vers les livrables et les publications des projets du 7e PC, ainsi que les liens vers certains types de résultats spécifiques tels que les jeux de données et les logiciels, sont récupérés dynamiquement sur OpenAIRE .

Livrables

Report on nearshore wave models

An account of the mathematical equations defining the nearshore wave model is given. The limitations of the model with respect to wave parameters and bathymetry are delineated, and the discretization and numerical implementation is outlined.

Report on Senigallia pilot

The Senigallia pilot site is characterized by a series of recent instrumentation aimed at monitoring the estuarine area of the Misa River, which flows into the Italian side of the Adriatic Sea.Field data are of different kinds and are collected at different locations, thus allowing one to calibrate and validate numerical models for riverine, estuarine and coastal applications. Water elevation, velocity and discharge are collected (only during flood events) in the final reach of the river by a stream gauge installed about 1 km upstream of the mouth. The offshore wave climate is recorded by an acoustic profiler located 4 km off the mouth, while a tide gauge located in the Senigallia harbor provides the tide oscillations. Furthermore, a video-monitoring station provides images that allow the reconstruction of the wave field and seabed bathymetry in the nearshore area.The data report will be based on both older and more recent recorded events, and will include data collected by both a newly installed X-band radar (that complements the video-monitoring station in the reconstruction of wave field and seabed bathymetry in the nearshore area) and an additional stream gauge, which will be installed in the coming months upstream of the present stream gauge. The new gauge will complement the old one recording events of smaller intensity, thus allowing its use for the calibration of numerical models in case of non-stormy events.

Report on urban flow and the transport of debris

Mathematical equations and numerical implementation

Report on river/estuarine hydrodynamics

Complete description of the governing 2D shallow water equations as an approximation of the 3D Navier-Stokes ones used to build the hydrodynamic models for river flow and estuarine flow; as well as numerical approximations used to solve them in terms of finite volumes with emphasis in the order of approximation used and time stability. Presentation of the performance of the numerical methods in GPU for some representative cases.

Social media and outreach materials

Social media accounts: Twitter, LinkedIn and Instagram; Outreach materials: a logo, a flyer and a motion-design video presenting the project will be produced.

Website

Website presenting the project and the participating organizations.

Publications

Lagrangian Acceleration as a Diagnostic for Wave Breaking in the Nearshore Zone

Auteurs: Rosa Maria Vargas‐Magaña, Henrik Kalisch, Marc Buckley, Maria Bjørnestad, Tessa Gronemann, Karoline Holand, Jochen Horstmann, Michael Streßer, Sébastien Fromenteau
Publié dans: Journal of Geophysical Research: Oceans, Numéro 131, 2026, ISSN 2169-9275
Éditeur: American Geophysical Union (AGU)
DOI: 10.1029/2024JC022193

Incorporating the vertical velocity in a coupled Lagrangian–Eulerian approach for particle transport in shallow flows

Auteurs: Vallés, P., Segovia-Burillo, J., Morales-Hernández, M., Roeber, V., and García-Navarro, P.:
Publié dans: Advances in Water Resources, Numéro 205, 2025
Éditeur: Elsevier
DOI: 10.1016/J.ADVWATRES.2025.105085__;

A novel energy-bounded Boussinesq model and a well balanced and stable numerical discretisation

Auteurs: Magnus Svärd, Henrik Kalisch
Publié dans: Journal of Computational Physics, Numéro 520, ISSN 1090-2716
Éditeur: Elsevier
DOI: 10.1016/J.JCP.2024.113516

Wave-driven current and vortex patterns at an open beach: Insights from phase-resolving numerical computations and Lagrangian measurements

Auteurs: Andreas Bondehagen, Volker Roeber, Henrik Kalisch, Marc P. Buckley, Michael Streßer, Marius Cysewski, Jochen Horstmann, Maria Bjørnestad, Olufemi E. Ige, Hege G. Frøysa, Ruben Carrasco-Alvarez
Publié dans: Coastal Engineering, Numéro 193, 2024, ISSN 0378-3839
Éditeur: Elsevier BV
DOI: 10.1016/J.COASTALENG.2024.104591

Probabilistic assessment of human instability in urban areas exposed to flood events

Auteurs: Gabriele Bernardini, Francesco Lagona, Marco Mingione, Matteo Postacchini
Publié dans: Scientific Reports, Numéro 15, 2025, ISSN 2045-2322
Éditeur: Springer Science and Business Media LLC
DOI: 10.1038/S41598-025-25267-Y

A 2D shallow water flow model with 1D internal boundary condition for subgrid-scale topography

Auteurs: P. Vallés, J. Fernández-Pato, M. Morales-Hernández, I. Echeverribar, P. García-Navarro
Publié dans: Advances in Water Resources, Numéro 189, 2024, ISSN 0309-1708
Éditeur: Elsevier BV
DOI: 10.1016/J.ADVWATRES.2024.104716

Mixing-phase model for shear-induced contractive/dilative effects in unsteady water-sediment mixture flows

Auteurs: S. Martínez-Aranda, J. Fernández-Pato, P. García-Navarro
Publié dans: Advances in Water Resources, Numéro 188, 2024, ISSN 0309-1708
Éditeur: Elsevier BV
DOI: 10.1016/J.ADVWATRES.2024.104710

Real-time ocean wave prediction in time domain with autoregression and echo state networks

Auteurs: Holand, Karoline; Kalisch, Henrik
Publié dans: Frontiers in Marine Science, Numéro 11, 2024, ISSN 2296-7745
Éditeur: Frontiers
DOI: 10.3389/FMARS.2024.1486234

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