耗散Peregrine-Boussinesq系统的振荡和正则激波

IF 1.4 4区数学 Q2 MATHEMATICS, APPLIED

IMA Journal of Applied Mathematics Pub Date : 2023-10-19 DOI:10.1093/imamat/hxad030

Larkspur Brudvik-Lindner, Dimitrios Mitsotakis, Athanasios E Tzavaras

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引用次数: 1

摘要

我们考虑一个耗散的、色散的Boussinesq型系统，它描述了在耗散起重要作用的情况下的波动现象。例如河流或海洋中的波浪形钻孔，湍流引起的耗散对其行为有显著影响。在这项研究中，我们证明了所提出的系统允许称为扩散-色散激波的行波解。根据色散和耗散效应之间的相互作用，这些解决方案可分为振荡激波和正则激波。通过将数值计算的解与实验室数据进行比较，我们观察到所提出的模型准确地捕获了波状孔在宽相速度范围内的行为。传统上，使用原始的Peregrine系统来近似波浪形钻孔，即使它不具有这些行波解，也倾向于在合适的时间尺度内提供精确的近似。为了解释这一现象，我们证明了耗散游隼系统解与非耗散游隼系统解之间的差异与耗散系数与观测时间的乘积成正比。

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Oscillatory and regularized shock waves for a dissipative Peregrine-Boussinesq system

Abstract We consider a dissipative, dispersive system of the Boussinesq type, which describes wave phenomena in scenarios where dissipation plays a significant role. Examples include undular bores in rivers or oceans, where turbulence-induced dissipation significantly influences their behavior. In this study, we demonstrate that the proposed system admits traveling wave solutions known as diffusive-dispersive shock waves. These solutions can be categorized as oscillatory and regularized shock waves, depending on the interplay between dispersion and dissipation effects. By comparing numerically computed solutions with laboratory data, we observe that the proposed model accurately captures the behavior of undular bores over a broad range of phase speeds. Traditionally, undular bores have been approximated using the original Peregrine system, which, even though it doesn’t possess these as traveling wave solutions, tends to offer accurate approximations within suitable time scales. To shed light on this phenomenon, we demonstrate that the discrepancy between the solutions of the dissipative Peregrine system and the non-dissipative counterpart is proportional to the product of the dissipation coefficient and the observation time.

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来源期刊

IMA Journal of Applied Mathematics 数学-应用数学

CiteScore

2.30

自引率

8.30%

发文量

审稿时长

24 months

期刊介绍： The IMA Journal of Applied Mathematics is a direct successor of the Journal of the Institute of Mathematics and its Applications which was started in 1965. It is an interdisciplinary journal that publishes research on mathematics arising in the physical sciences and engineering as well as suitable articles in the life sciences, social sciences, and finance. Submissions should address interesting and challenging mathematical problems arising in applications. A good balance between the development of the application(s) and the analysis is expected. Papers that either use established methods to address solved problems or that present analysis in the absence of applications will not be considered. The journal welcomes submissions in many research areas. Examples are: continuum mechanics materials science and elasticity, including boundary layer theory, combustion, complex flows and soft matter, electrohydrodynamics and magnetohydrodynamics, geophysical flows, granular flows, interfacial and free surface flows, vortex dynamics; elasticity theory; linear and nonlinear wave propagation, nonlinear optics and photonics; inverse problems; applied dynamical systems and nonlinear systems; mathematical physics; stochastic differential equations and stochastic dynamics; network science; industrial applications.