The mathematical fractional modeling of TiO_2 nanopowder synthesis by sol–gel method at low temperature

Sadek, Otmane; Sadek, Lakhlifa; Touhtouh, Samira; Hajjaji, A.

doi:10.23939/mmc2022.03.616

Cited by 13 publications

(4 citation statements)

References 36 publications

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“…□ Theorem 2. Let 𝑦(t) and 𝑦 m (t) represent the exact and approximate solutions of (5), respectively. The residual correction can be assigned to the estimation of the absolute error using the following procedure: [47] This error estimation can be used to check the accuracy of the results in the absence of knowledge of the exact 𝜒-FDE solution.…”

Section: Theorem 1 Suppose That the Function 𝑓mentioning

confidence: 99%

“…Similarly, the fractional integral of a function represents the integration of that function over a fractional order. Fractional calculus is a powerful tool for modeling [5] and understanding various physical, biological [6], and engineering processes such as viscoelasticity, diffusion, signal processing, and control systems [7][8][9]. Fractional calculus is used in many fields, including physics, engineering, finance, control theory, signal processing, and image processing.…”

Section: Introductionmentioning

confidence: 99%

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The general Bernstein function: Application to χ‐fractional differential equations

Sadek,

Sami Bataineh

2024

Math Methods in App Sciences

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In this paper, we present the general Bernstein functions for the first time. The properties of generalized Bernstein basis functions are given and demonstrated. The classical Bernstein polynomial bases are merely a subset of the general Bernstein functions. Based on the new Bernstein base functions and the collocation method, we present a numerical method for solving linear and nonlinear ‐fractional differential equations ( ‐FDEs) with variable coefficients. The fractional derivative used in this work is the ‐Caputo fractional derivative sense ( ‐CFD). Combining the Bernstein functions basis and the collocation methods yields the approximation solution of nonlinear differential equations. These base functions can be used to solve many problems in applied mathematics, including calculus of variations, differential equations, optimal control, and integral equations. Furthermore, the convergence of the method is rigorously justified and supported by numerical experiments.

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Section: Theorem 1 Suppose That the Function 𝑓mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The general Bernstein function: Application to χ‐fractional differential equations

Sadek,

Sami Bataineh

2024

Math Methods in App Sciences

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“…TiO 2 is an N-type semiconductor, which can be formed in three crystalline phases, rutile (tetragonal structure), brookite (orthorhombic structure) and anatase (tetragonal structure). In general, TiO2 is preferred in the anatase form due to its strong photocatalytic activity, as it has a more negative conduction band edge potential, is photochemically stable, has a high speci c surface area, is non-toxic, and relatively inexpensive [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

DFT study on the electronic, structure, magnetic and optical properties of TiO2 anatase

Sadek,

Touhtouh,

Hajjaji

2023

Preprint

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In this work, the electronic structure, magnetic and optical properties of the anatase phase of titanium dioxide (TiO2) were etudiée by the Density Functional Theory (DFT) method, using the GGA+U method. As a result, the magnetic electronic properties show that anatase is a non-magnetic semiconductor with an indirect gap of 3.202. Optical properties such as dielectric function, refractive index, extinction coefficient, reflectivity, absorption coefficient and conductivity were found to be 8.21, 2.91, 1.98, 0.532, 517000 cm-1 and 8.9 fs-1 respectively. These results are in agreement with the available experimental results.

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“…Also, another advantage of this definition is that the Caputo derivative of a constant is zero. Memory effect is an essential characteristic of fractional-order derivatives which made fractional calculus and its applications widely used in many fields of science and engineering [11,12,13,14,15,16,17]. Obviously, this feature is very relevant for modeling the spread of infections [18,19,20,21,22,23,24].…”

Section: Introductionmentioning

confidence: 99%

Stability characterization of a fractional-order viral system with the non-cytolytic immune assumption

Naim

Sabbar

Zeb

2022

mmnsa

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This article deals with a Caputo fractional-order viral model that incorporates the non-cytolytic immune hypothesis and the mechanism of viral replication inhibition. Firstly, we establish the existence, uniqueness, non-negativity, and boundedness of the solutions of the proposed viral model. Then, we point out that our model has the following three equilibrium points: equilibrium point without virus, equilibrium state without immune system, and equilibrium point activated by immunity with humoral feedback. By presenting two critical quantities, the asymptotic stability of all said steady points is examined. Finally, we examine the finesse of our results by highlighting the impact of fractional derivatives on the stability of the corresponding steady points.

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The mathematical fractional modeling of TiO_2 nanopowder synthesis by sol–gel method at low temperature

Cited by 13 publications

References 36 publications

The general Bernstein function: Application to χ‐fractional differential equations

The general Bernstein function: Application to χ‐fractional differential equations

DFT study on the electronic, structure, magnetic and optical properties of TiO2 anatase

Stability characterization of a fractional-order viral system with the non-cytolytic immune assumption

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