CMEMS-Based Coastal Analyses: Conditioning, Coupling and Limits for Applications

Agustin Sanchez-Arcilla; Joanna Staneva; Luigi Cavaleri; Merete Badger; Jean Bidlot; Jacob T. Sorensen; Lars B. Hansen; Adrien Martin; Andy Saulter; Manuel Espino; Mario M. Miglietta; Marc Mestres; Davide Bonaldo; Paolo Pezzutto; Johannes Schulz-Stellenfleth; Anne Wiese; Xiaoli Larsen; Sandro Carniel; Rodolfo Bolaños; Saleh Abdalla; Alessandro Tiesi

doi:10.3389/fmars.2021.604741

CMEMS-Based Coastal Analyses: Conditioning, Coupling and Limits for Applications

Agustin Sanchez-Arcilla^*, Joanna Staneva, Luigi Cavaleri, Merete Badger, Jean Bidlot, Jacob T. Sorensen, Lars B. Hansen, Adrien Martin, Andy Saulter, Manuel Espino, Mario M. Miglietta, Marc Mestres, Davide Bonaldo, Paolo Pezzutto, Johannes Schulz-Stellenfleth, Anne Wiese, Xiaoli Larsen, Sandro Carniel, Rodolfo Bolaños, Saleh AbdallaAlessandro Tiesi

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

Recent advances in numerical modeling, satellite data, and coastal processes, together with the rapid evolution of CMEMS products and the increasing pressures on coastal zones, suggest the timeliness of extending such products toward the coast. The CEASELESS EU H2020 project combines Sentinel and in-situ data with high-resolution models to predict coastal hydrodynamics at a variety of scales, according to stakeholder requirements. These predictions explicitly introduce land discharges into coastal oceanography, addressing local conditioning, assimilation memory and anisotropic error metrics taking into account the limited size of coastal domains. This article presents and discusses the advances achieved by CEASELESS in exploring the performance of coastal models, considering model resolution and domain scales, and assessing error generation and propagation. The project has also evaluated how underlying model uncertainties can be treated to comply with stakeholder requirements for a variety of applications, from storm-induced risks to aquaculture, from renewable energy to water quality. This has led to the refinement of a set of demonstrative applications, supported by a software environment able to provide met-ocean data on demand. The article ends with some remarks on the scientific, technical and application limits for CMEMS-based coastal products and how these products may be used to drive the extension of CMEMS toward the coast, promoting a wider uptake of CMEMS-based predictions.

Original language	English
Article number	180
Journal	Frontiers in Marine Science
Volume	8
Number of pages	25
ISSN	2296-7745
DOIs	https://doi.org/10.3389/fmars.2021.604741
Publication status	Published - 2021

Keywords

Oceanography
Coastal and regional
Coupled methods
Sentinel data
Downscaling
Coastal ocean applications

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Sanchez-Arcilla, A., Staneva, J., Cavaleri, L., Badger, M., Bidlot, J., Sorensen, J. T., Hansen, L. B., Martin, A., Saulter, A., Espino, M., Miglietta, M. M., Mestres, M., Bonaldo, D., Pezzutto, P., Schulz-Stellenfleth, J., Wiese, A., Larsen, X., Carniel, S., Bolaños, R., ... Tiesi, A. (2021). CMEMS-Based Coastal Analyses: Conditioning, Coupling and Limits for Applications. Frontiers in Marine Science, 8, [180]. https://doi.org/10.3389/fmars.2021.604741

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abstract = "Recent advances in numerical modeling, satellite data, and coastal processes, together with the rapid evolution of CMEMS products and the increasing pressures on coastal zones, suggest the timeliness of extending such products toward the coast. The CEASELESS EU H2020 project combines Sentinel and in-situ data with high-resolution models to predict coastal hydrodynamics at a variety of scales, according to stakeholder requirements. These predictions explicitly introduce land discharges into coastal oceanography, addressing local conditioning, assimilation memory and anisotropic error metrics taking into account the limited size of coastal domains. This article presents and discusses the advances achieved by CEASELESS in exploring the performance of coastal models, considering model resolution and domain scales, and assessing error generation and propagation. The project has also evaluated how underlying model uncertainties can be treated to comply with stakeholder requirements for a variety of applications, from storm-induced risks to aquaculture, from renewable energy to water quality. This has led to the refinement of a set of demonstrative applications, supported by a software environment able to provide met-ocean data on demand. The article ends with some remarks on the scientific, technical and application limits for CMEMS-based coastal products and how these products may be used to drive the extension of CMEMS toward the coast, promoting a wider uptake of CMEMS-based predictions.",

keywords = "Oceanography, Coastal and regional, Coupled methods, Sentinel data, Downscaling, Coastal ocean applications",

author = "Agustin Sanchez-Arcilla and Joanna Staneva and Luigi Cavaleri and Merete Badger and Jean Bidlot and Sorensen, {Jacob T.} and Hansen, {Lars B.} and Adrien Martin and Andy Saulter and Manuel Espino and Miglietta, {Mario M.} and Marc Mestres and Davide Bonaldo and Paolo Pezzutto and Johannes Schulz-Stellenfleth and Anne Wiese and Xiaoli Larsen and Sandro Carniel and Rodolfo Bola{\~n}os and Saleh Abdalla and Alessandro Tiesi",

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doi = "10.3389/fmars.2021.604741",

language = "English",

volume = "8",

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Sanchez-Arcilla, A, Staneva, J, Cavaleri, L, Badger, M, Bidlot, J, Sorensen, JT, Hansen, LB, Martin, A, Saulter, A, Espino, M, Miglietta, MM, Mestres, M, Bonaldo, D, Pezzutto, P, Schulz-Stellenfleth, J, Wiese, A, Larsen, X, Carniel, S, Bolaños, R, Abdalla, S & Tiesi, A 2021, 'CMEMS-Based Coastal Analyses: Conditioning, Coupling and Limits for Applications', Frontiers in Marine Science, vol. 8, 180. https://doi.org/10.3389/fmars.2021.604741

TY - JOUR

T1 - CMEMS-Based Coastal Analyses: Conditioning, Coupling and Limits for Applications

AU - Sanchez-Arcilla, Agustin

AU - Staneva, Joanna

AU - Cavaleri, Luigi

AU - Badger, Merete

AU - Bidlot, Jean

AU - Sorensen, Jacob T.

AU - Hansen, Lars B.

AU - Martin, Adrien

AU - Saulter, Andy

AU - Espino, Manuel

AU - Miglietta, Mario M.

AU - Mestres, Marc

AU - Bonaldo, Davide

AU - Pezzutto, Paolo

AU - Schulz-Stellenfleth, Johannes

AU - Wiese, Anne

AU - Larsen, Xiaoli

AU - Carniel, Sandro

AU - Bolaños, Rodolfo

AU - Abdalla, Saleh

AU - Tiesi, Alessandro

PY - 2021

Y1 - 2021

N2 - Recent advances in numerical modeling, satellite data, and coastal processes, together with the rapid evolution of CMEMS products and the increasing pressures on coastal zones, suggest the timeliness of extending such products toward the coast. The CEASELESS EU H2020 project combines Sentinel and in-situ data with high-resolution models to predict coastal hydrodynamics at a variety of scales, according to stakeholder requirements. These predictions explicitly introduce land discharges into coastal oceanography, addressing local conditioning, assimilation memory and anisotropic error metrics taking into account the limited size of coastal domains. This article presents and discusses the advances achieved by CEASELESS in exploring the performance of coastal models, considering model resolution and domain scales, and assessing error generation and propagation. The project has also evaluated how underlying model uncertainties can be treated to comply with stakeholder requirements for a variety of applications, from storm-induced risks to aquaculture, from renewable energy to water quality. This has led to the refinement of a set of demonstrative applications, supported by a software environment able to provide met-ocean data on demand. The article ends with some remarks on the scientific, technical and application limits for CMEMS-based coastal products and how these products may be used to drive the extension of CMEMS toward the coast, promoting a wider uptake of CMEMS-based predictions.

AB - Recent advances in numerical modeling, satellite data, and coastal processes, together with the rapid evolution of CMEMS products and the increasing pressures on coastal zones, suggest the timeliness of extending such products toward the coast. The CEASELESS EU H2020 project combines Sentinel and in-situ data with high-resolution models to predict coastal hydrodynamics at a variety of scales, according to stakeholder requirements. These predictions explicitly introduce land discharges into coastal oceanography, addressing local conditioning, assimilation memory and anisotropic error metrics taking into account the limited size of coastal domains. This article presents and discusses the advances achieved by CEASELESS in exploring the performance of coastal models, considering model resolution and domain scales, and assessing error generation and propagation. The project has also evaluated how underlying model uncertainties can be treated to comply with stakeholder requirements for a variety of applications, from storm-induced risks to aquaculture, from renewable energy to water quality. This has led to the refinement of a set of demonstrative applications, supported by a software environment able to provide met-ocean data on demand. The article ends with some remarks on the scientific, technical and application limits for CMEMS-based coastal products and how these products may be used to drive the extension of CMEMS toward the coast, promoting a wider uptake of CMEMS-based predictions.

KW - Oceanography

KW - Coastal and regional

KW - Coupled methods

KW - Sentinel data

KW - Downscaling

KW - Coastal ocean applications

U2 - 10.3389/fmars.2021.604741

DO - 10.3389/fmars.2021.604741

M3 - Journal article

SN - 2296-7745

VL - 8

JO - Frontiers in Marine Science

JF - Frontiers in Marine Science

M1 - 180

ER -

CMEMS-Based Coastal Analyses: Conditioning, Coupling and Limits for Applications

Abstract

Keywords

UN SDGs

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