Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves
Numerical computations for boulder transport have become a state-of-the-art tool for hindcasting the hydraulic processes associated with past storm wave and tsunami events. Since most previously developed two-dimensional formulations cater to boulders with symmetric outlines, they can consequently r...
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sg-ntu-dr.10356-1628232022-11-12T23:31:16Z Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves Watanabe, Masashi Yoshii, Takumi Roeber, Volker Goto, Kazuhisa Imamura, Fumihiko Earth Observatory of Singapore Science::Geology Coastal Boulder Boulder Transport Model Numerical computations for boulder transport have become a state-of-the-art tool for hindcasting the hydraulic processes associated with past storm wave and tsunami events. Since most previously developed two-dimensional formulations cater to boulders with symmetric outlines, they can consequently reproduce the transport distance and the velocity of boulders of cubic shape or similar structured geometries reasonably well. However, the formulations exhibit limitations when applied to rectangular- and flat-shaped boulders. The presently available formulations have difficulties reproducing the variations of frictional drag force due to the changes of the boulders' contact time with the ground. We have developed an extended boulder transport formulation and derived a new empirical roughness coefficient by considering the shape of boulders that accounts for the changes of the boulders' contact time with the ground. In comparison to other existing transport formulations, the present method provides superior accuracy of block velocity and transport distance in most cases - especially for boulders of rectangular geometry. Even by neglecting the full three-dimensional processes, numerical computations extended with the proposed boulder transport formulation can help explaining historic wave regimes, which were responsible for the transport of a variety of coastal boulders reported around the world. Submitted/Accepted version This research was financially supported by a Grant-in-Aid for JSPS fellows (project number 16J01953). 2022-11-10T07:50:17Z 2022-11-10T07:50:17Z 2023 Journal Article Watanabe, M., Yoshii, T., Roeber, V., Goto, K. & Imamura, F. (2023). Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves. Journal of Earthquake and Tsunami, 17(1), 2250018-. https://dx.doi.org/10.1142/S179343112250018X 1793-4311 https://hdl.handle.net/10356/162823 10.1142/S179343112250018X 2-s2.0-85133913619 1 17 2250018 en Journal of Earthquake and Tsunami Electronic version of an article published as Journal of Earthquake and Tsunami, 17(1), 2023, 2250018, https://doi.org/10.1142/S179343112250018X @ copyright World Scientific Publishing Company, https://www.worldscientific.com/doi/10.1142/S179343112250018X. application/pdf |
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Science::Geology Coastal Boulder Boulder Transport Model Watanabe, Masashi Yoshii, Takumi Roeber, Volker Goto, Kazuhisa Imamura, Fumihiko Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| description |
Numerical computations for boulder transport have become a state-of-the-art tool for hindcasting the hydraulic processes associated with past storm wave and tsunami events. Since most previously developed two-dimensional formulations cater to boulders with symmetric outlines, they can consequently reproduce the transport distance and the velocity of boulders of cubic shape or similar structured geometries reasonably well. However, the formulations exhibit limitations when applied to rectangular- and flat-shaped boulders. The presently available formulations have difficulties reproducing the variations of frictional drag force due to the changes of the boulders' contact time with the ground. We have developed an extended boulder transport formulation and derived a new empirical roughness coefficient by considering the shape of boulders that accounts for the changes of the boulders' contact time with the ground. In comparison to other existing transport formulations, the present method provides superior accuracy of block velocity and transport distance in most cases - especially for boulders of rectangular geometry. Even by neglecting the full three-dimensional processes, numerical computations extended with the proposed boulder transport formulation can help explaining historic wave regimes, which were responsible for the transport of a variety of coastal boulders reported around the world. |
| author2 |
Earth Observatory of Singapore |
| author_facet |
Earth Observatory of Singapore Watanabe, Masashi Yoshii, Takumi Roeber, Volker Goto, Kazuhisa Imamura, Fumihiko |
| format |
Article |
| author |
Watanabe, Masashi Yoshii, Takumi Roeber, Volker Goto, Kazuhisa Imamura, Fumihiko |
| author_sort |
Watanabe, Masashi |
| title |
Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| title_short |
Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| title_full |
Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| title_fullStr |
Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| title_full_unstemmed |
Derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| title_sort |
derivation, validation, and numerical implementation of a two-dimensional boulder transport formulation by coastal waves |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/162823 |
| _version_ |
1751548541643259904 |