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On the Mathematical Analysis of Generalized Quantum-Nabla Fractional Fluid Models with Dissipative Nonlinearities

Shaher Momani, Rabha W. Ibrahim

2025Contemporary Mathematics6 citationsDOIOpen Access PDF

Abstract

We investigate a nonlinear fluid system governed by the generalized quantum-Caputo nabla fractional operator, capturing nonlocal memory effects in velocity, shear stress, and fluidity. The system is formulated with polynomial nonlinearities and modeled over the unit disk. We establish a general existence and uniqueness theorem for mild solutions in the function spaces H1(D)3, H2(D)3, and ℓ∞(D)3, based on fixed-point theory and the integral representation of the fractional operators. Under mild dissipativity assumptions, we prove boundedness and asymptotic stability using generalized (q, τ )-Mittag-Leffler decay. Furthermore, we present illustrative examples for each functional space and validate the theoretical results with numerical simulations. The findings provide a rigorous and flexible framework for modeling fractional fluid dynamics with memory-driven dissipation.

Topics & Concepts

MathematicsDissipative systemUniquenessNonlinear systemStability (learning theory)Applied mathematicsMathematical analysisNabla symbolFractional calculusRepresentation (politics)Space (punctuation)Function spacePolynomialGeneralized functionFunction (biology)Extension (predicate logic)Exponential stabilityWeak solutionFluid dynamicsGeneralized inverseFractional Differential Equations SolutionsNanofluid Flow and Heat TransferRheology and Fluid Dynamics Studies
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