Long wave runup on piecewise linear topographies

UTKU KÂNOĞLU; COSTAS EMMANUEL SYNOLAKIS

doi:10.1017/S0022112098002468

Abstract

We study long-wave evolution and runup on piecewise linear one- and two-dimensional bathymetries analytically and experimentally with the objective of understanding certain coastal effects of tidal waves. We develop a general solution method for determining the amplification factor of different ocean topographies consisting of linearly varying and constant-depth segments to study how spectral distributions evolve over bathymetry, and apply our results to study the evolution of solitary waves. We find asymptotic results which suggest that solitary waves often interact with piecewise linear topographies in a counter-intuitive manner. We compare our analytical predictions with numerical results, with results from a new set of laboratory experiments from a physical model of Revere Beach, and also with the data on wave runup around an idealized conical island. We find good agreement between our theory and the laboratory results for the time histories of free-surface elevations and for the maximum runup heights. Our results suggest that, at least for simple piecewise linear topographies, analytical methods can be used to calculate effectively some important physical parameters in long-wave runup. Also, by underscoring the effects of the topographic slope at the shoreline, this analysis qualitatively suggests why sometimes predictions of field-applicable numerical models differ substantially from observations of tsunami runup.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Lin, Pengzhi Chang, Kuang-An and Liu, Philip L.-F. 1999. Runup and Rundown of Solitary Waves on Sloping Beaches. Journal of Waterway, Port, Coastal, and Ocean Engineering, Vol. 125, Issue. 5, p. 247.

Zhang, Jin E. Wu, Theodore Y. and Hou, Thomas Y. 2001. Advances in Applied Mechanics Volume 37. Vol. 37, Issue. , p. 89.

Synolakis, Costas E. Bardet, Jean-Pierre Borrero, José C. Davies, Hugh L. Okal, Emile A. Silver, Eli A. Sweet, Suzanne and Tappin, David R. 2002. The slump origin of the 1998 Papua New Guinea Tsunami. Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences, Vol. 458, Issue. 2020, p. 763.

Okal, Emile A. and Synolakis, Costas E. 2004. Source discriminants for near-field tsunamis. Geophysical Journal International, Vol. 158, Issue. 3, p. 899.

Liu, Huan-Wen Lin, Pengzhi and Shankar, N.Jothi 2004. An analytical solution of the mild-slope equation for waves around a circular island on a paraboloidal shoal. Coastal Engineering, Vol. 51, Issue. 5-6, p. 421.

Gedik, N. Irtem, E. and Kabdasli, S. 2005. Laboratory investigation on tsunami run-up. Ocean Engineering, Vol. 32, Issue. 5-6, p. 513.

Borrero, José C. Sieh, Kerry Chlieh, Mohamed and Synolakis, Costas E. 2006. Tsunami inundation modeling for western Sumatra. Proceedings of the National Academy of Sciences, Vol. 103, Issue. 52, p. 19673.

Gedik, Nuray Irtem, Emel and Kabdasli, M. Sedat 2006. Experimental Investigation on Solitary Wave Run-Down and Its Effects on Armor Units. Coastal Engineering Journal, Vol. 48, Issue. 4, p. 337.

Weiss, Robert Wünnemann, Kai and Bahlburg, Heinrich 2006. Numerical modelling of generation, propagation and run-up of tsunamis caused by oceanic impacts: model strategy and technical solutions. Geophysical Journal International, Vol. 167, Issue. 1, p. 77.

Synolakis, Costas E and Bernard, Eddie N 2006. Tsunami science before and beyond Boxing Day 2004. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 364, Issue. 1845, p. 2231.

Berry, M.V 2007. Focused tsunami waves. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 463, Issue. 2087, p. 3055.

Lin, Pengzhi and Liu, Huan-Wen 2007. Scattering and Trapping of Wave Energy by a Submerged Truncated Paraboloidal Shoal. Journal of Waterway, Port, Coastal, and Ocean Engineering, Vol. 133, Issue. 2, p. 94.

Lynett, Patrick J. 2007. Effect of a Shallow Water Obstruction on Long Wave Runup and Overland Flow Velocity. Journal of Waterway, Port, Coastal, and Ocean Engineering, Vol. 133, Issue. 6, p. 455.

Liu, Huan-Wen and Li, Yan-Bao 2007. An analytical solution for long-wave scattering by a submerged circular truncated shoal. Journal of Engineering Mathematics, Vol. 57, Issue. 2, p. 133.

Postacioglu, Nazmi and Özeren, M. Sinan 2008. A semi-spectral modelling of landslide tsunamis. Geophysical Journal International, Vol. 175, Issue. 1, p. 1.

Didenkulova, I. I. Zahibo, N. and Pelinovsky, E. N. 2008. Reflection of long waves from a “nonreflecting” bottom profile. Fluid Dynamics, Vol. 43, Issue. 4, p. 590.

Fuhrman, David R. and Madsen, Per A. 2008. Simulation of nonlinear wave run-up with a high-order Boussinesq model. Coastal Engineering, Vol. 55, Issue. 2, p. 139.

Synolakis, C. E. Bernard, E. N. Titov, V. V. Kânoğlu, U. and González, F. I. 2008. Tsunami Science Four Years after the 2004 Indian Ocean Tsunami. p. 2197.

Ewing, Lesley C. 2008. Considering Sea Level Rise as a Coastal Hazard. p. 117.

Hsiao, Shih-Chun Hsu, Tai-Wen Lin, Ting-Chieh and Chang, Yu-Hsuan 2008. On the evolution and run-up of breaking solitary waves on a mild sloping beach. Coastal Engineering, Vol. 55, Issue. 12, p. 975.

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Long wave runup on piecewise linear topographies

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