Abstract
Integral equations are essential tools in various areas of applied mathematics. A computational approach to solving an integral equation is important in scientific research. The Haar wavelet collocation method (HWCM) with operational matrices of integration is one famous method which has been applied to solve systems of linear integral equations. In this paper, an approximated analytical method based on the Haar wavelet collocation method is applied to the system of diffusion convection partial differential equations with initial and boundary conditions. This system determines the enzymatic glucose fuel cell with the chemical reaction rate of the Morrison equation. The enzymatic glucose fuel cell model describes the concentration of glucose and hydrogen ion that can be converted into energy. During the process, the model reduces to the linear integral equation system including computational Haar matrices. The computational Haar matrices can be computed by HWCM coding in the Maple program. Illustrated examples are provided to demonstrate the preciseness and effectiveness of the proposed method. The results are shown as numerical solutions of glucose and hydrogen ion.
Highlights
In biology and chemistry systems, partial differential equations (PDEs) play a role in various processes in the structure of human beings, such as the carbon dioxide (CO2) and oxygen (O2) diffusions in the bloodstream [4], oxygen diffusion in absorbing tissue [13], enzyme kinetics reaction mechanisms [1], enzymatic glucose fuel cell [23], etc
We introduce the Haar wavelet collocation method (HWCM) and apply this method to find an approximate analytical solution of the enzymatic glucose fuel cell with the Morrison equation model
Some numerical results for the glucose and hydrogen ion concentrations in the enzymatic glucose fuel cell model can be shown as the approximate analytical solutions
Summary
Nonlinear differential equations (NDEs) play significant roles in various areas of applied sciences, for example, mathematical biology, fluid mechanics, chemical kinetics, temperature distribution, reaction-diffusion system, industrial process, and plasma physics. The Haar wavelet method is used as a mathematical tool for reaction-diffusion partial differential equations in many applications [8] such as chemical reactions, biological chemistry and fluid mechanics. The glucose concentration ([CG]) and the hydrogen ion concentration ([CH+ ]) can be determined by the model of the transport equation with the reaction rates of the Morrison equation as. We introduce the Haar wavelet collocation method (HWCM) and apply this method to find an approximate analytical solution of the enzymatic glucose fuel cell with the Morrison equation model. A reaction occurs in which the glucose and enzyme become gluconic acid (C6H12O7), hydrogen ion and
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