A note on tsunamis: their generation and propagation in an ocean of uniform depth

The waves generated in a two-dimensional fluid domain of infinite lateral extent and uniform depth by a deformation of the bounding solid boundary are investigated both theoretically and experimentally. An integral solution is developed for an arbitrary bed displacement (in space and time) on the basis of a linear approximation of the complete (nonlinear) description of wave motion. Experimental and theoretical results are presented for two specific deformations of the bed; the spatial variation of each bed displacement consists of a block section of the bed moving vertically either up or down while the time-displacement history of the block section is varied. The presentation of results is divided into two sections based on two regions of the fluid domain: a generation region in which the bed deformation occurs and a downstream region where the bed position remains stationary for all time. The applicability of the linear approximation in the generation region is investigated both theoretically and experimentally; results are presented which enable certain gross features of the primary wave leaving this region to be determined when the magnitudes of parameters which characterize the bed displacement are known. The results indicate that the primary restriction on the applicability of the linear theory during the bed deformation is that the total amplitude of the bed displacement must remain small compared with the uniform water depth; even this restriction can be relaxed for one type of bed motion. Wave behaviour in the downstream region of the fluid domain is discussed with emphasis on the gradual growth of nonlinear effects relative to frequency dispersion during propagation and the subsequent breakdown of the linear theory. A method is presented for finding the wave behaviour in the far field of the downstream region, where the effects of nonlinearities and frequency dispersion have become about equal. This method is based on the use of a model equation in the far field (which includes both linear and nonlinear effects in an approximate manner) first used by Peregrine (1966) and more recently advocated by Benjamin, Bona & Mahony (1972) as a preferable model to the more commonly used equation of Korteweg & de Vries (1895). An input-output approach is illustrated for the numerical solution of this equation where the input is computed from the linear theory in its region of applicability. Computations are presented and compared with experiment for the case of a positive bed displacement where the net volume of the generated wave is finite and positive; the results demonstrate the evolution of a train of solitary waves (solitons) ordered by amplitude followed by a dispersive train of oscillatory waves. The case of a negative bed displacement in which the net wave volume is finite and negative (and the initial wave is negative almost everywhere) is also investigated; the results suggest that only a dispersive train of waves evolves (no solitons) for this case.

[1]  D. Korteweg,et al.  XLI. On the change of form of long waves advancing in a rectangular canal, and on a new type of long stationary waves , 1895 .

[2]  Dr. M. G. Worster Methods of Mathematical Physics , 1947, Nature.

[3]  Philip M. Morse,et al.  Methods of Mathematical Physics , 1947, The Mathematical Gazette.

[4]  R. Courant,et al.  Methods of Mathematical Physics , 1962 .

[5]  G. H. Keulegan Gradual damping of solitary waves , 1948 .

[6]  Takashi Ichiye,et al.  On the theory of Tsunami , 1950 .

[7]  H. Honda,et al.  The waves caused by one-dimensional deformation of the bottom of shallow sea of uniform depth , 1951 .

[8]  F. Ursell,et al.  The long-wave paradox in the theory of gravity waves , 1953, Mathematical Proceedings of the Cambridge Philosophical Society.

[9]  Kohei Nakamura On the Waves Caused by the Deformation of the Bottom of the Sea,I , 1953 .

[10]  T. Ichiye A Theory on the Generation of Tsunamis by an Impulse at the Sea Bottom , 1958 .

[11]  Kinjiro Kajiura,et al.  The Leading Wave of a Tsunami , 1963 .

[12]  W. G. V. Dorn SOURCE MECHANISM OF THE TSUNAMI OP MARCH 28, 1964 IN ALASKA , 1964 .

[13]  N. Zabusky,et al.  Interaction of "Solitons" in a Collisionless Plasma and the Recurrence of Initial States , 1965 .

[14]  D. Peregrine Calculations of the development of an undular bore , 1966, Journal of Fluid Mechanics.

[15]  W. G. Van Dorn,et al.  Boundary dissipation of oscillatory waves , 1966, Journal of Fluid Mechanics.

[16]  C. S. Gardner,et al.  Method for solving the Korteweg-deVries equation , 1967 .

[17]  R. E. Meyer Note on the undular jump , 1967, Journal of Fluid Mechanics.

[18]  P. Lax INTEGRALS OF NONLINEAR EQUATIONS OF EVOLUTION AND SOLITARY WAVES. , 1968 .

[19]  Norman J. Zabusky,et al.  Solitons and Bound States of the Time-Independent Schrödinger Equation , 1968 .

[20]  G. Plafker Tectonics of the March 27, 1964, Alaska earthquake: Chapter I in The Alaska earthquake, March 27, 1964: regional effects , 1969 .

[21]  J. A. French,et al.  Wave uplift pressures on horizontal platforms , 1969 .

[22]  J. Hammack,et al.  Tsunamis - a model of their generation and propagation , 1972 .

[23]  J. Bona,et al.  Model equations for long waves in nonlinear dispersive systems , 1972, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[24]  Li-San Hwang,et al.  Long wave generation on a sloping beach , 1972, Journal of Fluid Mechanics.

[25]  198 ON THE THEORY OF OSCILLATORY WAVES , 2022 .