Abstract

Abstract This paper investigates the question of the existence of nonlinear wave–ice interaction with the focus on nonlinear wave propagation and dispersion of waves. The scope of this investigation is to provide a better understanding of ice and wave conditions required to observe nonlinear wave effects under level ice. Direct numerical simulations of nonlinear waves in solid ice are performed within the weakly nonlinear Schrödinger equation (NLSE) framework, using the theoretical findings from Liu and Mollo-Christensen’s 1988 paper. Systematic variations of wave and ice parameters address the impact of the mechanical ice properties and ice thickness on traveling waves of certain wave lengths. The impacts of parameter characteristics on nonlinear focusing and wave dynamics, as well as possible constraints regarding physical consistency, are discussed. It is presented that nonlinear focusing in level ice occurs theoretically. Hereby, distinctive areas of validity with respect to nonlinear wave focusing are identified within the parameter study, which strongly depends on the material properties of the level ice. The results obtained in the parameter study are subsequently used to investigate wave focusing under level ice. Therefore, an exact solution of the NLSE, the Peregrine breather, is utilized. The analytical solution for level ice is compared to the open water solution and accompanied by direct numerical simulations. These investigations show that nonlinear wave focusing can be predicted under level ice for certain parameters. In addition, the agreement of the direct simulations and the analytic solution verifies the numerical approach for nonlinear waves in solid ice.

Highlights

  • The climate in cold regions is subjected to changes where waves and ice increasingly interact

  • The brine volume is a function of the sea water salinity Sw, on the wave group properties, namely carrier wave number and the sea ice temperature Ti, which is between −0.5 ◦C k0, group velocity cg and carrier angular frequency ω0. and −22.9 ◦C [31]

  • Note that compression is suppressed in this simulation setup, which results in different wave number and ice thickness compared to the ones provided by Liu and Mollo-Christensen [11]

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Summary

Institutional Repository Cover Sheet

ASME Paper Title: Investigation of nonlinear wave-ice interaction using parameter study and numerical simulation. N. Hartmann, Franz von Bock und Polach, Sören Ehlers, Norbert Hoffmann, Miguel Onorato, Marco Klein.

Accepted Manuscript Not Copyedited
Ship Structural Design and Analysis Hamburg University of Technology
Introduction
This paper connects both research fields by giving in section
For potential flows the nonlinear boundary conditions in the
Intense wave events
Results and Discussion
Focusing ratio
NLSE time domain simulation with open water and ice boundary condition
Peregrine breather in open water
Peregrine breather in ice covered water
Conclusion
List of Tables

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