CFD simulation of nonlinear deep-water wave instabilities involving wave breaking

Extreme waves at the sea surface can have severe impacts on marine structures. One of the theoretical mechanisms leading to extreme waves is the instability of deep-water wave trains subject to initially small perturbations, which then grow exponentially. The present study focuses on the two-dimensi...

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Bibliographic Details
Published in:Volume 6: Ocean Engineering
Main Authors: Li, Yuzhu, Fuhrman, David R.
Format: Other Non-Article Part of Journal/Newspaper
Language:English
Published: American Society of Mechanical Engineers 2021
Subjects:
Arctic
Online Access:https://orbit.dtu.dk/en/publications/ab536aeb-5eae-452d-bb94-94f9682aa6ac
https://doi.org/10.1115/OMAE2021-62805
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spelling ftdtupubl:oai:pure.atira.dk:publications/ab536aeb-5eae-452d-bb94-94f9682aa6ac 2023-05-15T14:23:03+02:00 CFD simulation of nonlinear deep-water wave instabilities involving wave breaking Li, Yuzhu Fuhrman, David R. 2021 https://orbit.dtu.dk/en/publications/ab536aeb-5eae-452d-bb94-94f9682aa6ac https://doi.org/10.1115/OMAE2021-62805 eng eng American Society of Mechanical Engineers info:eu-repo/semantics/closedAccess Li , Y & Fuhrman , D R 2021 , CFD simulation of nonlinear deep-water wave instabilities involving wave breaking . in Proceedings of the ASME 2021 40th International Conference on Ocean, Offshore and Arctic Engineering . vol. 6: Ocean Engineering , V006T06A065 , American Society of Mechanical Engineers , 40th International Conference on Ocean, Offshore and Arctic Engineering (OMAE2021) , 21/06/2021 . https://doi.org/10.1115/OMAE2021-62805 contributionToPeriodical 2021 ftdtupubl https://doi.org/10.1115/OMAE2021-62805 2023-01-12T00:15:59Z Extreme waves at the sea surface can have severe impacts on marine structures. One of the theoretical mechanisms leading to extreme waves is the instability of deep-water wave trains subject to initially small perturbations, which then grow exponentially. The present study focuses on the two-dimensional Benjamin–Feir (or modulational) instability and the three-dimensional crescent (or horseshoe) waves, also known as Class I and Class II instabilities, respectively. Numerical studies on Class I and Class II wave instabilities to date have been limited to models founded on potential flow theory, thus they could only properly investigate the process from initial growth of the perturbations to the initial breaking point. The present study conducts numerical simulations to investigate the generation and development of wave instabilities involving the wave breaking process. A CFD model solving Reynolds-averaged Navier-Stokes (RANS) equations coupled with turbulence closure in terms of the anisotropic Reynolds stress model is applied. Wave form evolutions, Fourier amplitudes, and the turbulence beneath the broken waves are investigated. Other Non-Article Part of Journal/Newspaper Arctic Technical University of Denmark: DTU Orbit Volume 6: Ocean Engineering
institution Open Polar
collection Technical University of Denmark: DTU Orbit
op_collection_id ftdtupubl
language English
description Extreme waves at the sea surface can have severe impacts on marine structures. One of the theoretical mechanisms leading to extreme waves is the instability of deep-water wave trains subject to initially small perturbations, which then grow exponentially. The present study focuses on the two-dimensional Benjamin–Feir (or modulational) instability and the three-dimensional crescent (or horseshoe) waves, also known as Class I and Class II instabilities, respectively. Numerical studies on Class I and Class II wave instabilities to date have been limited to models founded on potential flow theory, thus they could only properly investigate the process from initial growth of the perturbations to the initial breaking point. The present study conducts numerical simulations to investigate the generation and development of wave instabilities involving the wave breaking process. A CFD model solving Reynolds-averaged Navier-Stokes (RANS) equations coupled with turbulence closure in terms of the anisotropic Reynolds stress model is applied. Wave form evolutions, Fourier amplitudes, and the turbulence beneath the broken waves are investigated.
format Other Non-Article Part of Journal/Newspaper
author Li, Yuzhu
Fuhrman, David R.
spellingShingle Li, Yuzhu
Fuhrman, David R.
CFD simulation of nonlinear deep-water wave instabilities involving wave breaking
author_facet Li, Yuzhu
Fuhrman, David R.
author_sort Li, Yuzhu
title CFD simulation of nonlinear deep-water wave instabilities involving wave breaking
title_short CFD simulation of nonlinear deep-water wave instabilities involving wave breaking
title_full CFD simulation of nonlinear deep-water wave instabilities involving wave breaking
title_fullStr CFD simulation of nonlinear deep-water wave instabilities involving wave breaking
title_full_unstemmed CFD simulation of nonlinear deep-water wave instabilities involving wave breaking
title_sort cfd simulation of nonlinear deep-water wave instabilities involving wave breaking
publisher American Society of Mechanical Engineers
publishDate 2021
url https://orbit.dtu.dk/en/publications/ab536aeb-5eae-452d-bb94-94f9682aa6ac
https://doi.org/10.1115/OMAE2021-62805
genre Arctic
genre_facet Arctic
op_source Li , Y & Fuhrman , D R 2021 , CFD simulation of nonlinear deep-water wave instabilities involving wave breaking . in Proceedings of the ASME 2021 40th International Conference on Ocean, Offshore and Arctic Engineering . vol. 6: Ocean Engineering , V006T06A065 , American Society of Mechanical Engineers , 40th International Conference on Ocean, Offshore and Arctic Engineering (OMAE2021) , 21/06/2021 . https://doi.org/10.1115/OMAE2021-62805
op_rights info:eu-repo/semantics/closedAccess
op_doi https://doi.org/10.1115/OMAE2021-62805
container_title Volume 6: Ocean Engineering
_version_ 1766295531398627328

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