Akademik Veri Yönetim Sistemi
COMPUTATIONAL MATHEMATICS AND MODELING, cilt.36, ss.1-16, 2025 (Scopus)
The 3 + 1‑dimensional Boiti-Leon-Manna-Pempinelli equation, a well-known higher-dimensional extension of the shallow-water wave model, has been taken into account. This article focuses on exploring the nonlinear dispersion mechanism by considering the wave velocity factor to analyze the behavior of incompressible fluids. To do this, two analytical methodologies are suggested, and solutions are generated that simulate many varieties of traveling waves under particular constraining circumstances. The stability of the equation considered in the study has beenevaluated using a linear stability analysis method that examines the effects of small-amplitude perturbations on the solution. The nonlinear wave distribution in the x direction is examined by selecting one of these solutions, which is the model of the time-dependent behavior of incompressible fluids, and by assigning the proper values to the constants that keep the system stable. In addition, while comparing the advantages and limitations of the two analytical methods, the study also draws attention to the strong physical correlation between diffusion, absorption, and wave velocity. Since wave velocity is scientifically related to energy per unit space or time, it has been concluded that high-energy waves propagate and diffuse more rapidly. The steady-state stability of the equation, which is the model of the nonlinear distribution, is determined by stimulated Raman scattering, group velocity distribution, and eigen-phase modulation. It has been argued that fluid flow modeling, simulation, and use of analytical results can help throughout the design phase to produce safe and useful products.