TY - JOUR
T1 - Structure-preserving Numerical Method for Maxwell-Ampère Nernst-Planck Model
AU - Qiao, Zhonghua
AU - Xu, Zhenli
AU - Yin, Qian
AU - Zhou, Shenggao
N1 - Funding Information:
This work is supported by the CAS AMSS-PolyU Joint Laboratory of Applied Mathematics . Z. Qiao's work is partially supported by the Hong Kong Research Grants Council ( RFS Project No. RFS2021-5S03 and GRF project No. 15302919 ) and the Hong Kong Polytechnic University internal grant No. 1-9B7B . The work of Z. Xu and Q. Yin is partially supported by NSFC (grant No. 12071288 ), Science and Technology Commission of Shanghai Municipality (grant No. 20JC1414100 and 21JC1403700 ), the Strategic Priority Research Program of CAS (grant No. XDA25010403 ) and the HPC center of Shanghai Jiao Tong University . S. Zhou's work is partially supported by the National Natural Science Foundation of China 12171319 and Science and Technology Commission of Shanghai Municipality (grant No. 21JC1403700 ).
Publisher Copyright:
© 2022 Elsevier Inc.
PY - 2023/2/15
Y1 - 2023/2/15
N2 - Charge dynamics play essential role in many practical applications such as semiconductors, electrochemical devices and transmembrane ion channels. A Maxwell-Ampère Nernst-Planck (MANP) model that describes charge dynamics via concentrations and the electric displacement is able to take effects beyond mean-field approximations into account. To obtain physically faithful numerical solutions, we develop a structure-preserving numerical method for the MANP model whose solution has several physical properties of importance. By the Slotboom transform with entropic-mean approximations, a positivity preserving scheme with Scharfetter-Gummel fluxes is derived for the generalized Nernst-Planck equations. To deal with the curl-free constraint, the dielectric displacement from the Maxwell-Ampère equation is further updated with a local relaxation algorithm of linear computational complexity. We prove that the proposed numerical method unconditionally preserves the mass conservation and the solution positivity at the discrete level, and satisfies the discrete energy dissipation law with a time-step restriction. Numerical experiments verify that our numerical method has expected accuracy and structure-preserving properties. Applications to ion transport with large convection, arising from boundary-layer electric field and Born solvation interactions, further demonstrate that the MANP formulation with the proposed numerical scheme has attractive performance and can effectively describe charge dynamics with large convection of high numerical cell Péclet numbers.
AB - Charge dynamics play essential role in many practical applications such as semiconductors, electrochemical devices and transmembrane ion channels. A Maxwell-Ampère Nernst-Planck (MANP) model that describes charge dynamics via concentrations and the electric displacement is able to take effects beyond mean-field approximations into account. To obtain physically faithful numerical solutions, we develop a structure-preserving numerical method for the MANP model whose solution has several physical properties of importance. By the Slotboom transform with entropic-mean approximations, a positivity preserving scheme with Scharfetter-Gummel fluxes is derived for the generalized Nernst-Planck equations. To deal with the curl-free constraint, the dielectric displacement from the Maxwell-Ampère equation is further updated with a local relaxation algorithm of linear computational complexity. We prove that the proposed numerical method unconditionally preserves the mass conservation and the solution positivity at the discrete level, and satisfies the discrete energy dissipation law with a time-step restriction. Numerical experiments verify that our numerical method has expected accuracy and structure-preserving properties. Applications to ion transport with large convection, arising from boundary-layer electric field and Born solvation interactions, further demonstrate that the MANP formulation with the proposed numerical scheme has attractive performance and can effectively describe charge dynamics with large convection of high numerical cell Péclet numbers.
KW - Convection dominated problem
KW - Energy dissipation
KW - Local curl-free algorithm
KW - Maxwell–Ampère Nernst–Planck equations
KW - Poisson-Nernst-Planck equations
KW - Positivity preserving
UR - http://www.scopus.com/inward/record.url?scp=85144354656&partnerID=8YFLogxK
U2 - 10.1016/j.jcp.2022.111845
DO - 10.1016/j.jcp.2022.111845
M3 - Journal article
AN - SCOPUS:85144354656
SN - 0021-9991
VL - 475
SP - 1
EP - 20
JO - Journal of Computational Physics
JF - Journal of Computational Physics
M1 - 111845
ER -