Your search keyword '"-Rahman, Saeed-ur"' showing total 6 results

1. Solutions for a flame propagation model in porous media based on Hamiltonian and regular perturbation methods.

Author

Rahman, Saeed ur and Díaz Palencia, José Luis

Subjects

*POROUS materials, *FORCED convection, *MATHEMATICAL models, *TEMPERATURE, *EQUATIONS

Abstract

This article extends the exploration of solutions to the issue of flame propagation driven by pressure and temperature in porous media that we introduced in earlier papers. We continue to consider a p-Laplacian type operator as a mathematical formalism to model slow and fast diffusion effects, that can be given in the non-homogeneous propagation of flames. In addition, we introduce a forced convection to model any possible induced flow in the porous media. We depart from previously known models to further substantiate our driving equations. From a mathematical standpoint, our goal is to deepen in the understanding of the general behavior of solutions via analyzing their regularity, boundedness, and uniqueness. We explore stationary solutions through a Hamiltonian approach and employ a regular perturbation method. Subsequently, nonstationary solutions are derived using a singular exponential scaling and, once more, a regular perturbation approach. [ABSTRACT FROM AUTHOR]

Published

2024

2. New regularity criteria for an MHD Darcy-Forchheimer fluid.

Author

Rahman, Saeed ur and Palencia, José Luis Díaz

Subjects

*ONE-dimensional flow, *FLUID flow, *FLUIDS, *POROUS materials, *VORTEX motion, *DARCY'S law

Abstract

The purpose of the presented article is to develop some new global regularity criteria for a magnetohydrodynamic (MHD) fluid flowing in a saturated porous medium. The effect of the porous medium, over the fluid flow, is characterized by a Darcy–Forchheimer law. The fluid, under study, is considered as one-dimensional and flowing in the x– direction with velocity component u. In addition, such a component is assumed to vary with the y– direction, i.e. u (y). Then, given the vorticity function w = - ∂ u ∂ y , such that ‖ w ‖ BMO 2 is sufficiently small, we develop the regularity criteria under the scope of the L 2 space. We extend our results to the spaces Ls , where s > 2. Afterward, we prove the Liouville-type theorem for the MHD Darcy–Forchheimer flow equation. Eventually, we obtain some characterization about the asymptotic behaviour of solutions, particularly, the nonuniform convergence in L 2 for t → ∞. [ABSTRACT FROM AUTHOR]

Published

2024

3. Analytical and Computational Approaches for Bi-Stable Reaction and p-Laplacian Diffusion Flame Dynamics in Porous Media.

Author

Rahman, Saeed ur and Díaz Palencia, José Luis

Subjects

*POROUS materials, *TRAVELING waves (Physics), *FLAME, *PERTURBATION theory, *SINGULAR perturbations, *FLAME temperature, *DIFFUSION

Abstract

In this paper, we present a mathematical approach for studying the changes in pressure and temperature variables in flames. This conception extends beyond the traditional second-order Laplacian diffusion model by considering the p-Laplacian operator and a bi-stable reaction term, thereby providing a more generalized framework for flame diffusion analysis. Given the structure of our equations, we provide the boundedness and uniqueness of the solutions in a weak sense from both analytical and numerical approaches. We further reformulate the governing equations in the context of traveling wave solutions, applying singular geometric perturbation theory to derive the analytical expressions of these profiles. This theoretical development is complemented by numerical assessments, which not only validate our theoretical predictions, but also optimize the traveling wave speed to minimize the error between numerical and analytical solutions. Additionally, we explore self-similar structured solutions. The paper then concludes with a perspective on future research, with emphasis being placed on the need for experimental validation in laboratory settings. Such empirical studies could test the robustness of our model and allow for refinement based on actual measurements, thereby broadening the applicability and accuracy of our findings in practical scenarios. [ABSTRACT FROM AUTHOR]

Published

2024

4. Regularity criteria for a two dimensional Erying-Powell fluid flowing in a MHD porous medium.

Author

Palencia, José Luis Díaz, Rahman, Saeed Ur, and Hanif, Saman

Subjects

*DEGENERATE parabolic equations, *VELOCITY, *POROUS materials, *INTEGERS, *LAPLACIAN matrices

Abstract

The intention and novelty in the presented study were to develop the regularity analysis for a parabolic equation describing a type of Eyring-Powell fluid flow in two dimensions. We proved that, under certain general conditions involving the space of bounded mean oscillation ( ) and the Lebesgue space , there exist bounded and regular velocity solutions under the space scope. This conclusion was additionally supplemented by the condition of a finite square integrable initial data (also some of the obtained expressions involved the gradient and the laplacian of the initial velocity distribution). To make our results further general, the proposed analysis was extended to cover regularity results in spaces. As a remarkable conclusion, we highlight that the solutions to the two dimensional Eyring-Powell fluid flow did not exhibit blow up behaviour. [ABSTRACT FROM AUTHOR]

Published

2022

5. Regularity and Travelling Wave Profiles for a Porous Eyring–Powell Fluid with Darcy–Forchheimer Law.

Author

Díaz Palencia, José Luis, Rahman, Saeed ur, Redondo, Antonio Naranjo, and Roa González, Julián

Subjects

*PERTURBATION theory, *FLUID flow, *POROUS materials, *FLUIDS, *REYNOLDS number, *DARCY'S law

Abstract

The goal of this study is to provide analytical and numerical assessments to a fluid flow based on an Eyring–Powell viscosity term and a Darcy–Forchheimer law in a porous media. The analysis provides results about regularity, existence and uniqueness of solutions. Travelling wave solutions are explored, supported by the Geometric Perturbation Theory to build profiles in the proximity of the equation critical points. Finally, a numerical routine is provided as a baseline for the validity of the analytical approach presented for low Reynolds numbers typical in a porous medium. [ABSTRACT FROM AUTHOR]

Published

2022

6. Regularity, Asymptotic Solutions and Travelling Waves Analysis in a Porous Medium System to Model the Interaction between Invasive and Invaded Species.

Author

Díaz Palencia, José Luis, Roa González, Julián, Rahman, Saeed Ur, and Redondo, Antonio Naranjo

Subjects

POROUS materials, WAVE analysis, INTRODUCED species, PERTURBATION theory, ADVECTION

Abstract

This work provides an analytical approach to characterize and determine solutions to a porous medium system of equations with views in applications to invasive-invaded biological dynamics. Firstly, the existence and uniqueness of solutions are proved. Afterwards, profiles of solutions are obtained making use of the self-similar structure that permits showing the existence of a diffusive front. The solutions are then studied within the Travelling Waves (TW) domain showing the existence of potential and exponential profiles in the stable connection that converges to the stationary solutions in which the invasive species predominates. The TW profiles are shown to exist based on the geometry perturbation theory together with an analytical-topological argument in the phase plane. The finding of an exponential decaying rate (related with the advection and diffusion parameters) in the invaded species TW is not trivial in the nonlinear diffusion case and reflects the existence of a TW trajectory governed by the invaded species runaway (in the direction of the advection) and the diffusion (acting in a finite speed front or support). [ABSTRACT FROM AUTHOR]

Published

2022