9129767 DHGXILVC 1 apa 50 date desc year Matsumoto 18 https://himatsumoto.scrippsprofiles.ucsd.edu/wp-content/plugins/zotpress/
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%20of%20the%20driving%20erosion%20forces%20and%20the%20flexibility%20provided%20by%20a%20grid%20discretization%20scheme.%20Initial%20model%20testing%20shows%20the%20development%20of%20varied%20rocky%20profile%20geometries%2C%20ranging%20from%20steep%20plunging%20cliffs%2C%20cliffs%20with%20narrow%20benches%2C%20and%20cliffs%20with%20a%20variety%20of%20shore%20platform%20shapes.%20Most%20of%20the%20model%20geometries%20are%20similar%20to%20those%20observed%20in%20the%20field%2C%20and%20model%20behavior%20is%20robust%20and%20internally%20consistent%20across%20a%20relatively%20large%20parameter%20space.%20This%20paper%20provides%20a%20detailed%20description%20of%20the%20new%20model%20and%20its%20subsequent%20testing.%20Emphasis%20is%20placed%20on%20comparison%20of%20model%20results%20with%20published%20field%20observations%20in%20which%20morphometric%20relationships%20are%20described%20between%20shore%20platform%20gradient%20and%20tidal%20range%2C%20and%20platform%20elevation%20and%20platform%20width.%20The%20model%20adequately%20simulates%20these%20morphometric%20relationships%2C%20while%20retaining%20its%20ability%20to%20simulate%20a%20wide%20range%20of%20profile%20shapes.%20The%20simplicity%20of%20process%20representations%2C%20and%20the%20limited%20number%20of%20processes%20implemented%2C%20means%20that%20model%20outputs%20can%20be%20interpreted%20reasonably%20easily.%20Hence%2C%20an%20opportunity%20is%20now%20provided%2C%20following%20the%20testing%20described%20in%20this%20paper%2C%20to%20use%20the%20model%20to%20systematically%20investigate%20the%20broader%20controlling%20conditions%20on%20rock%20shore%20profile%20development.%22%2C%22date%22%3A%222016%5C%2F09%22%2C%22language%22%3A%22%22%2C%22DOI%22%3A%2210.1016%5C%2Fj.geomorph.2016.05.017%22%2C%22ISSN%22%3A%220169-555X%22%2C%22url%22%3A%22%22%2C%22collections%22%3A%5B%22DHGXILVC%22%5D%2C%22dateModified%22%3A%222022-08-31T22%3A54%3A30Z%22%7D%7D%5D%7D
Siegelman, M. N., McCarthy, R. A., Young, A. P., O’Reilly, W., Matsumoto, H., Johnson, M., Mack, C., & Guza, R. T. (2024). Subaerial Profiles at Two Beaches: Equilibrium and Machine Learning. Journal of Geophysical Research: Earth Surface, 129(10), e2023JF007524. https://doi.org/10.1029/2023JF007524
Dickson, M. E., Matsumoto, H., Stephenson, W. J., Swirad, Z. M., Thompson, C. F., & Young, A. P. (2023). Sea-level rise may not uniformly accelerate cliff erosion rates. Nature Communications, 14(1), 8485. https://doi.org/10.1038/s41467-023-44149-3
Blenkinsopp, C. E., Bayle, P. M., Martins, K., Foss, O. W., Almeida, L. P., Kaminsky, G. M., Schimmels, S., & Matsumoto, H. (2022). Wave runup on composite beaches and dynamic cobble berm revetments. Coastal Engineering, 176, 15. https://doi.org/10.1016/j.coastaleng.2022.104148
Matsumoto, H., Young, A. P., & Carilli, J. E. (2022). Modeling the relative influence of environmental controls on marine terrace widths. Geomorphology, 396, 11. https://doi.org/10.1016/j.geomorph.2021.107986
Matsumoto, H., & Young, A. P. (2022). Quantitative regional observations of gravel and bedrock influence on beach morphologies. Geomorphology, 419, 108491. https://doi.org/10.1016/j.geomorph.2022.108491
Matsumoto, H., Dickson, M. E., & Kench, P. S. (2021). Preservation and destruction of Holocene marine terraces: The effects of episodic versus gradual relative sea level change. Geophysical Research Letters, 48(19), 8. https://doi.org/10.1029/2021gl094543
Young, A. P., Guza, R. T., Matsumoto, H., Merrifield, M. A., O’Reilly, W. C., & Swirad, Z. M. (2021). Three years of weekly observations of coastal cliff erosion by waves and rainfall. Geomorphology, 375. https://doi.org/10.1016/j.geomorph.2020.107545
Matsumoto, H., Young, A. P., & Guza, R. T. (2020). Cusp and mega cusp observations on a mixed sediment beach. Earth and Space Science, 7(10). https://doi.org/10.1029/2020ea001366
Matsumoto, H., Young, A. P., & Guza, R. T. (2020). Observations of surface cobbles at two southern California beaches. Marine Geology, 419. https://doi.org/10.1016/j.margeo.2019.106049
Matsumoto, H., Dickson, M. E., & Kench, P. S. (2018). Modelling the relative dominance of wave erosion and weathering processes in shore platform development in micro- to mega-tidal settings. Earth Surface Processes and Landforms, 43(12), 2642–2653. https://doi.org/10.1002/esp.4422
Matsumoto, H., & Young, A. (2018). Automated cobble mapping of a mixed sand-cobble beach using a mobile LiDAR system. Remote Sensing, 10(8), 1253. https://doi.org/10.3390/rs10081253
Matsumoto, H., Dickson, M. E., & Masselink, G. (2017). Systematic analysis of rocky shore platform morphology at large spatial scale using LiDAR-derived digital elevation models. Geomorphology, 286, 45–57. https://doi.org/10.1016/j.geomorph.2017.03.011
Matsumoto, H., Dickson, M. E., & Kench, P. S. (2016). An exploratory numerical model of rocky shore profile evolution. Geomorphology, 268, 98–109. https://doi.org/10.1016/j.geomorph.2016.05.017