A computational approach for the study of electromagnetic interactions in reacting flows

TL;DR

This paper introduces EMI, a CFD methodology coupling electromagnetic fields with reacting flows, validated through simulations showing electromagnetic effects influence flame behavior and charged species dynamics.

Contribution

The paper presents a novel computational framework integrating electromagnetic interactions with reacting flow simulations using a coupled FDTD and Navier-Stokes approach.

Findings

EMI accurately captures electromagnetic effects on reacting flows.

Electromagnetic fields influence flame shape and reactivity.

Validation against analytical and numerical solutions confirms model reliability.

Abstract

A computational fluid dynamics methodology for the simulation of electromagnetic interactions in compressible reacting flows has been formulated. The developed code, named EMI, is based on the SENGA Direct Numerical Simulation (DNS) software. Static electric and magnetic fields are solved using Gauss's laws of Maxwell's equations. Electromagnetic wave propagation is solved by discretizing Ampere's and Faraday's equations using the explicit Finite-Difference Time-Domain (FDTD) method. The equations for the electromagnetic fields are fully coupled with the Navier-Stokes equations, such that interactions between the electromagnetic fields and the fluid are included in the formulation. The interaction terms include the Lorentz, polarization, and magnetization forces. These forces determine volume forces that affect the transport of momentum, the diffusion velocity, and the energy conservation equations. In addition, the medium's properties affect the propagation of the electromagnetic fields via electrical permittivity and conductivity, charge density, and magnetic permeability. The solution of electromagnetic fields is validated against analytical and numerical solutions. The implementation of the coupling between electromagnetic fields and conservation equations for species, energy, and momentum is validated with laminar reacting flow numerical solutions from the literature. The capabilities of the formulation are investigated for a range of laminar methane-air computations under electrostatic, magnetostatic, and high-frequency electromagnetic waves. The validity of the electrostatic formulation in the presence of currents related to the movement of charged species is also assessed. Results demonstrate that EMI-SENGA can capture the fundamental effects of electromagnetic fields on reacting flows and the dynamics of charged species and their effect on flame shape and reactivity.