Akademik Veri Yönetim Sistemi
European Physical Journal Plus, cilt.140, sa.7, 2025 (SCI-Expanded)
This study investigates the concatenation model having parabolic law with nonlocal nonlinearity, which describes pulse propagation in optical fibers, and explores the effects of nonlinear and dispersive terms on pulse dynamics. The model is a concatenation of the Lakshmanan–Porsezian–Daniel and the Sasa–Satsuma equations and provides a unique framework for examining the interplay between various nonlinearities and dispersion. We derive optical soliton solutions, including bright and W-shape like solitons, using the new Kudryashov method, demonstrating the model’s capacity to support diverse soliton waveforms. Additionally, we perform a modulation instability analysis to assess the stability characteristics of the system, highlighting the influence of key parameters such as nonlinear coefficients and dispersive coefficients on the onset and growth rate of instability. The effects of these parameters on soliton behavior are extensively explored through 2D and 3D graphical representations. Our findings reveal rare solution types for this novel concatenation model, offering insights into the conditions under which MI appears and the impact of various parameters on soliton dynamics. The model’s flexibility in handling both nonlinear and dispersive effects positions it as a significant tool in optical soliton studies, with potential applications in stochastic, fractional, and bifurcation analyses for future research.