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Dispersion-Governed Lump Waves in a Generalized Calogero–Bogoyavlenskii–Schiff-like Model with Spatially Symmetric Nonlinearity

Wen‐Xiu Ma

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Abstract

This study investigates lump wave structures that arise from the interplay of dispersion and nonlinearity in a generalized Calogero–Bogoyavlenskii–Schiff-like model with spatially symmetric nonlinearity in (2+1) dimensions. A generalized bilinear representation of the governing equation is formulated using extended bilinear derivatives of the fourth order, providing a convenient framework for analytic treatment. Through symbolic computation, we construct positive quadratic wave solutions, which give rise to rationally localized lump wave tructures that decay algebraically in all spatial directions at fixed time. Analysis shows that the critical points of these quadratic waves lie along a straight line in the spatial plane and propagate at a constant velocity. Along this characteristic trajectory, the amplitudes of the lump waves remain essentially unchanged, reflecting the stability of these coherent structures. The emergence of these lumps is primarily driven by the combined influence of five dispersive terms in the model, highlighting the crucial role of higher-order dispersion in balancing the nonlinear interactions and shaping the resulting localized waveforms.

Topics & Concepts

Quadratic equationNonlinear systemBilinear interpolationMathematicsMathematical analysisDispersion (optics)Rogue wavePlane (geometry)AmplitudeRepresentation (politics)Stability (learning theory)Plane waveClassical mechanicsPhysicsBilinear formWave propagationLine (geometry)Constant (computer programming)Dispersion relationKadomtsev–Petviashvili equationReal lineSolitonQuadratic functionWave equationSurface waveParabolaGeometryOrientation (vector space)Nonlinear Waves and SolitonsNonlinear Photonic SystemsNonlocal and gradient elasticity in micro/nano structures