AbstractThe mathematical description of localized solitons in the presence of large‐scale waves is a fundamental problem in nonlinear science, with applications in fluid dynamics, nonlinear optics, and condensed matter physics. Here, the evolution of a soliton as it interacts with a rarefaction wave or a dispersive shock wave, examples of slowly varying and rapidly oscillating dispersive mean fields, for the Korteweg–de Vries equation is studied. Step boundary conditions give rise to either a rarefaction wave (step up) or a dispersive shock wave (step down). When a soliton interacts with one of these mean fields, it can either transmit through (tunnel) or become embedded (trapped) inside, depending on its initial amplitude and position. A topical review of three separate analytical approaches is undertaken to describe these interactions. First, a basic soliton perturbation theory is introduced that is found to capture the solution dynamics for soliton–rarefaction wave interaction in the small dispersion limit. Next, multiphase Whitham modulation theory and its finite‐gap description are used to describe soliton–rarefaction wave and soliton–dispersive shock wave interactions. Lastly, a spectral description and an exact solution of the initial value problem is obtained through the inverse scattering transform. For transmitted solitons, far‐field asymptotics reveal the soliton phase shift through either type of wave mentioned above. In the trapped case, there is no proper eigenvalue in the spectral description, implying that the evolution does not involve a proper soliton solution. These approaches are consistent, agree with direct numerical simulation, and accurately describe different aspects of solitary wave–mean field interaction.

More from our Archive

• DOI: 10.3390/computation11070143 2023

  Mathematical Modelling of Tuberculosis Outbreak in an East African Country Incorporating Vaccination and Treatment

  Kayode Oshinubi, Olumuyiwa James Peter, Emmanuel Addai, Enock Mwizerwa, Oluwatosin Babasola, Ifeoma Veronica Nwabufo, Ibrahima Sane, Umar Muhammad Adam, Adejimi Adeniji, Janet O. Agbaje

• DOI: 10.1063/5.0154516 2023

  Two-dimensional memristive hyperchaotic maps with different coupling frames and its hardware implementation

  Mengjiao Wang, Mingyu An, Shaobo He, Xinan Zhang, Herbert Ho-Ching Iu, Zhijun Li

• DOI: 10.1002/cnm.3750 2023

  Mandibular bone remodeling around osseointegrated functionally graded biomaterial implant using three dimensional finite element model

  Sameh Elleuch, Hanen Jrad, Mondher Wali, Fakhreddine Dammak

• DOI: 10.21272/hem.2023.2-02 2023

  Issues concerning Social Security, Medicare and the national debt

  Paul F. Gentle

• DOI: 10.1002/zamm.202300077 2023

  Mathematical modelling of heat and solutal rate with cross‐diffusion effect on the flow of nanofluid past a curved surface under the impact of thermal radiation and heat source: Sensitivity analysis

  Thirupathi Thumma, Subhajit Panda, S. R. Mishra, Surender Ontela

• DOI: 10.1111/sapm.12619 2023

  Rogue waves in the massive Thirring model

  Junchao Chen, Bo Yang, Bao‐Feng Feng

• DOI: 10.1002/nme.7326 2023

  Multiscale modeling of linear elastic heterogeneous structures via localized model order reduction

  Philipp Diercks, Karen Veroy, Annika Robens‐Radermacher, Jörg F. Unger

• DOI: 10.1093/nargab/lqad066 2023

  Mge-cluster: a reference-free approach for typing bacterial plasmids

  Sergio Arredondo-Alonso, Rebecca A Gladstone, Anna K Pöntinen, João A Gama, Anita C Schürch, Val F Lanza, Pål Jarle Johnsen, Ørjan Samuelsen, Gerry Tonkin-Hill, Jukka Corander

• DOI: 10.1111/sapm.12615 2023

  Soliton–mean field interaction in Korteweg–de Vries dispersive hydrodynamics

  Mark J. Ablowitz, Justin T. Cole, Gennady A. El, Mark A. Hoefer, Xu‐Dan Luo

• DOI: 10.3390/asi6040063 2023

  Bibliometric Trends in Industry 5.0 Research: An Updated Overview

  Dag Øivind Madsen, Terje Berg, Mario Di Nardo