In this study, we investigate the propagation dynamics of the M-truncated fractional paraxial wave equation arising in liquid crystal models. We construct exact analytical soliton solutions and analyze their structural and dynamical properties under fractional-order effects. By applying a traveling wave transformation, the governing equation is reduced to an ordinary differential form. A couple of efficient analytical schemes, such as the extended Jacobi elliptic function technique and the (G′/G)-expansion method, are used to find a variety of exact solutions. The solutions include hyperbolic, trigonometric, rational, and elliptic soliton forms. Several classes of wave structures are obtained, such as parabolic, peaked, periodic, cnoidal, asymptotic, and breather-type solitons. Particular parameter choices yield explicit solution families that clarify the effect of model coefficients. Graphical representations in terms of modulus, real, and imaginary parts illustrate the physical behavior and propagation characteristics of the obtained wave solutions. A comparative discussion between fractional-order and integer-order soliton solutions is also presented. The results demonstrate that the fractional paraxial model admits rich soliton dynamics and provides a flexible framework for describing nonlinear optical wave propagation in liquid crystal media and related photonic systems.
Ouahid et al. (Thu,) studied this question.