A Mathematical Model for Transport and Growth of Microbes in Unsaturated Porous Soil

In this work, we develop a mathematical model for transport and growth of microbes by natural (rain) water infiltration and flow through unsaturated porous soil along the vertical direction under gravity and capillarity by coupling a system of advection diffusion equations (for concentration of micr...

Full description

Saved in:
Bibliographic Details
Published in:Mathematical problems in engineering 2021-12, Vol.2021, p.1-13
Main Authors: Timsina, Ramesh Chandra, Khanal, Harihar, Ludu, Andrei, Uprety, Kedar Nath
Format: Article
Language:English
Subjects:
Adsorption
Biological effects
Biomass
Boundary conditions
Capillarity
Dynamical systems
Engineering
Exact solutions
Finite volume method
Flow velocity
Hydraulics
Mathematical models
Microorganisms
Moisture content
Motility
Nonlinear dynamics
Nonlinear systems
Partial differential equations
Pollutants
Pressure head
Reaction-diffusion equations
Runge-Kutta method
Soil bacteria
Soil dynamics
Soil porosity
Soil stresses
Solitary waves
Substrates
Transport equations
Traveling waves
Unsaturated flow
Unsaturated soils
Wave propagation
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:In this work, we develop a mathematical model for transport and growth of microbes by natural (rain) water infiltration and flow through unsaturated porous soil along the vertical direction under gravity and capillarity by coupling a system of advection diffusion equations (for concentration of microbes and their growth-limiting substrate) with the Richards equation. The model takes into consideration several major physical, chemical, and biological mechanisms. The resulting coupled system of PDEs together with their boundary conditions is highly nonlinear and complicated to solve analytically. We present both a partial analytic approach towards solving the nonlinear system and finding the main type of dynamics of microbes, and a full-scale numerical simulation. Following the auxiliary equation method for nonlinear reaction-diffusion equations, we obtain a closed form traveling wave solution for the Richards equation. Using the propagating front solution for the pressure head, we reduce the transport equation to an ODE along the moving frame and obtain an analytic solution for the history of bacteria concentration for a specific test case. To solve the system numerically, we employ upwind finite volume method for the transport equations and stabilized explicit Runge–Kutta–Legendre super-time-stepping scheme for the Richards equation. Finally, some numerical simulation results of an infiltration experiment are presented, providing a validation and backup to the analytic partial solutions for the transport and growth of bacteria in the soil, stressing the occurrence of front moving solitons in the nonlinear dynamics.
ISSN:1024-123X
1563-5147
DOI:10.1155/2021/6278126