Marching-on-in-Degree Time-Domain Integral Equation Solver for Transient Electromagnetic Analysis of Graphene

Abstract: Abstract:The marching-on-in-degree (MOD) time-domain integral equation (TDIE) solver for the transient electromagnetic scattering of the graphene is presented in this paper. Graphene's dispersive surface impedance is approximated using rational function expressions of complex conjugate pole-residue pairs with the vector fitting (VF) method. Enforcing the surface impedance boundary condition, TDIE is established and solved in the MOD scheme, where the temporal surface impedance is carefully convoluted with the … Show more

“…Graphene is a promising 2D material in a wide variety of applications, e.g., THz devices [1], metamaterial [1,2], power generation [3], transmission lines and components anticorrosion [4,5], heat management [6,7], super capacitor [8], electromagnetic interference (EMI) shielding [9], electronic skin [10], etc. Time domain full-wave numerical methods [11][12][13][14][15][16][17][18] are critical in transient electromagnetic analysis, and the time domain integral equation (TDIE) of surface electric currents has been solved successfully with the marching-on-in-degree (MOD) method to analyze the monolayer graphene in free space [18].…”

“…After summing the monolayer graphene surface conductivity [22,23], the MLG surface conductivity/resistivity 2 of 13 are approximated by vector fitting (VF) [24], which is a popular tool in power systems and microwave engineering communities [11,[25][26][27][28]. Then, the analytical convolution of temporal surface resistivity and electric current density, as well as surface conductivity and magnetic current density, can be deduced [18].…”

Transient Electromagnetic Analysis of Multilayer Graphene with Dielectric Substrate Using Marching-on-in-Degree Method

“…Graphene is a promising 2D material in a wide variety of applications, e.g., THz devices [1], metamaterial [1,2], power generation [3], transmission lines and components anticorrosion [4,5], heat management [6,7], super capacitor [8], electromagnetic interference (EMI) shielding [9], electronic skin [10], etc. Time domain full-wave numerical methods [11][12][13][14][15][16][17][18] are critical in transient electromagnetic analysis, and the time domain integral equation (TDIE) of surface electric currents has been solved successfully with the marching-on-in-degree (MOD) method to analyze the monolayer graphene in free space [18].…”

“…After summing the monolayer graphene surface conductivity [22,23], the MLG surface conductivity/resistivity 2 of 13 are approximated by vector fitting (VF) [24], which is a popular tool in power systems and microwave engineering communities [11,[25][26][27][28]. Then, the analytical convolution of temporal surface resistivity and electric current density, as well as surface conductivity and magnetic current density, can be deduced [18].…”

Transient Electromagnetic Analysis of Multilayer Graphene with Dielectric Substrate Using Marching-on-in-Degree Method

Transient Analysis of Few-layer Graphene Using Marching-on-in-degree TDIE