Acta mathematica scientia, Series B >

2022 , Vol. 42 >Issue 3: 1081 - 1102

DOI: https://doi.org/10.1007/s10473-022-0315-5

Articles

THE TIME DECAY RATES OF THE CLASSICAL SOLUTION TO THE POISSON-NERNST-PLANCK-FOURIER EQUATIONS IN $\mathbb{R}^3$

  • Leilei TONG ,
  • Zhong TAN ,
  • Xu ZHANG
Expand
  • 1. School of Science, Chongqing University of Posts and Telecommunications, Chongqing, 400065, China;
    2. School of Mathematical Sciences and Fujian Provincial Key Laboratory on Mathematical Modeling & High Performance Scientific Computing, Xiamen University, Xiamen, 361005, China;
    3. School of Mathematics and Statistics, Zhengzhou University, Zhengzhou, 450001, China

Received date: 2020-11-18

  Revised date: 2021-04-08

  Online published: 2022-06-24

Supported by

The work of the first author was supported by the National Natural Science Foundation of China (12001077), the Science and Technology Research Program of Chongqing Municipal Education Commission (KJQN202000618) and Chongqing University of Posts and Telecommunications startup fund (A2018-128). The second author was supported by the National Natural Science Foundation of China (11926316, 11531010). The third author was supported by National Natural Science Foundation of China (11901537).

Fold

Abstract

In this work, the Poisson-Nernst-Planck-Fourier system in three dimensions is considered. For when the initial data regards a small perturbation around the constant equilibrium state in a $H^3\cap\dot{H}^{-s} (0\leq s\leq 1/2)$ norm, we obtain the time convergence rate of the global solution by a regularity interpolation trick and an energy method.

Key words: Poisson-Nernst-Planck-Fourier system; decay rates; energy method

Cite this article

Leilei TONG , Zhong TAN , Xu ZHANG . THE TIME DECAY RATES OF THE CLASSICAL SOLUTION TO THE POISSON-NERNST-PLANCK-FOURIER EQUATIONS IN $\mathbb{R}^3$[J]. Acta mathematica scientia, Series B, 2022 , 42(3) : 1081 -1102 . DOI: 10.1007/s10473-022-0315-5

References

[1] Barcilon V, Chen D P, Eisenberg R S, Jerome J. Qualitative properties of steady-state Poisson-Nernst-Planck systems:perturbation and simulation study. SIAM J Appl Math, 1997, 57:631-648
[2] Biler P, Dolbeault J. Long Time Behavior of Solutions to Nernst-Planck and Debye-Hückel Drift-Diffusion Systems. Annales Henri Poincaré, 2000, 1:461-472
[3] Biler P, Hebisch W, Nadzieja T. The Debye system:existence and large time behavior of solutions. Nonlinear Anal, 1994, 23:1189-1209
[4] Bazant M Z, Thornton K, Ajdari A. Diffuse-charge dynamics in electrochemical systems. Physical review E, 2004, 70:021,506
[5] Cesare P, Moriondo A, Vellani V, McNaughton P A. Ion channels gated by heat. Proc Natl Acad Sci USA, 1999, 96:7658-7663
[6] Deng C, Li C M. Endpoint bilinear estimates and applications to the two-dimensional Poisson-Nernst-Planck system. Nonlinearity, 2013, 26:2993-3009
[7] Duan R J, Ruan L Z, Zhu C J. Optimal decay rates to conservation laws with diffusion-type terms of regularity-gain and regularity-loss. Math Models Methods Appl Sci, 2012, 22:1250012 39 pp
[8] Eisenberg R S. Computing the field in proteins and channels. J Membrane Biol, 1996, 150:1-25
[9] Eisenberg R S. From structure to function in open ionic channels. J Membrane Biol, 1999, 171:1-24
[10] Elad D, Gavish N. Finite domain effects in steady state solutions of Poisson-Nernst-Planck equations. SIAM J Appl Math, 2019, 79:1030-1050
[11] Eisenberg B, Liu W S. Poisson-Nernst-Planck systems for ion channels with permanent charges. SIAM J Math Anal, 2007, 38:1932-1966
[12] Gajewski H. On existence, uniqueness and asymptotic behavior of solutions of the basic equations for carrier transport in semiconductors. Z Angew Math Mech, 1985, 65:101-108
[13] Gagneux G, Millet O. A survey on properties of Nernst-Planck-Poisson system. Application to ionic transport in porous media. Appl Math Model, 2016, 40:846-858
[14] Guo Y, Wang Y J. Decay of dissipative equations and negative Sobolev spaces. Commun Part Diff Equ, 2012, 37:2165-2208
[15] Hsieh C Y. Global existence of solutions for the Poisson-Nernst-Planck system with steric effects. Nonlinear Anal Real World Appl, 2019, 50:34-54
[16] Hsieh C Y, Lin T C. Exponential decay estimates for the stability of boundary layer solutions to poisson-nernst-planck systems:One spatial dimension case. SIAM J Appl Math, 2015, 47:3442-3465
[17] Hsieh C Y, Lin T C, Liu C, Liu P. Global existence of the non-isothermal Poisson-Nernst-Planck-Fourier system. J Differential Equations, 2020, 269:7287-7310
[18] Jerome J W. Analysis of charge transport. A mathematical study of semiconductor devices. Berlin:Springer-Verlag, 1996
[19] Jordan P C, Bacquet R J, McCammon J A, Tran P. How electrolyte shielding influences the electrical potential in transmembrane ion channels. Biophysical Journal, 1989, 55:1041-1052
[20] Ji L J, Liu P, Xu Z L, Zhou S G. Asymptotic analysis on dielectric boundary effects of modified Poisson-Nernst-Planck equations. SIAM J Appl Math, 2018, 78:1802-1822
[21] Jiang N, Luo Y L, Zhang X. Long time stability of admissible equilibria in Poisson-Nernst-Planck-Fourier system. arXiv:1910.04094
[22] Liu W S. Geometric singular perturbation approach to steady-state Poisson-Nernst-Planck systems. SIAM J Appl Math, 2005, 65:754-766
[23] Lin T C, Eisenberg B. A new approach to the lennard-jones potential and a new model:Pnp-steric equations. Commun Math Sci, 2014, 12:149-173
[24] Lin T C, Eisenberg B. Multiple solutions of steady-state Poisson-Nernst-Planck equations with steric effects. Nonlinearity, 2015, 28:2053-2080
[25] Liu P, Wu S, Liu C. Non-isothermal electrokinetics:energetic variational approach. Commun Math Sci, 2018, 16:1451-1463
[26] Liu W S, Xu H G. A complete analysis of a classical Poisson-Nernst-Planck model for ionic flow. J Differential Equations, 2015, 258:1192-1228
[27] Mock M S. An initial value problem from semiconductor device theory. SIAM J Math Anal, 1974, 5:597-612
[28] Matsumura A, Nishida T. The initial value problem for the equations of motion of viscous and heat-conductive gases. J Math Kyoto Univ, 1980, 20:67-104
[29] Markowich P A, Ringhofer C A, Schmeiser C. Semiconductor equations. Vienna:Springer-Verlag, 1990
[30] Nirenberg L. On elliptic partial differential equations. Ann Scuola Norm Sup Pisa Cl Sci, 1959, 13:115-162
[31] Nonner W, Chen D P, Eisenberg B. Progress and prospects in permeation. J Gen Physiol, 1999, 113:773-782
[32] Ogawa T, Shimizu S. The drift-diffusion system in two-dimensional critical Hardy space. J Funct Anal, 2008, 255:1107-1138
[33] Park J H, Jerome J W. Qualitative properties of steady-state Poisson-Nernst-Planck systems:Mathematical study. SIAM J Appl Math, 1997, 57:609-630
[34] Promislow K, Stockie J M. Adiabatic relaxation of convective-diffusive gas transport in a porous fuel cell electrode. SIAM J Appl Math, 2001, 62:180-205
[35] Reubish D S, Emerling D E, DeFalco J, Steiger D, Victoria C L, Vincent F. Functional assessment of temperature-gated ion-channel activity using a real-time PCR machine. BioTechniques, 2009, 47:iii-ix. PMID:19852757
[36] Stein E M. Singular Integrals and Differentiability Properties of Functions. Princeton Mathematical Series. No 30. Princeton, NJ:Princeton University Press, 1970
[37] Sohr H. The Navier-Stokes equations. Birkhäuser Advanced Texts:Basler Lehrbücher. Basel:Birkhäuser Verlag, 2001
[38] Song Z L, Cao X L, Huang H X. Electroneutral models for a multidimensional dynamic Poisson-Nernst-Planck system. Phys Rev E, 2018, 98:032404
[39] Schoch R B, Han J, Renaud P. Transport phenomena in nanofluidics. Rev Mod Phys, 2008, 80:839
[40] Schuss Z, Nadler B, Eisenberg R S. Derivation of Poisson and Nernst-Planck equations in a bath and channel from a molecular model. Phys Rev E, 2001, 64:036116
[41] Wu Y S, Tan Z. Asymptotic behavior of the Stokes approximation equations for compressible flows in R3. Acta Mathematica Scientia, 2015, 35B(3):746-760
[42] Zhang Y H, Wu G C. Global existence and asymptotic behavior for the 3D compressible non-isentropic Euler equations with damping. Acta Mathematica Scientia, 2014, 34B(2):424-434
Options
Outlines

/

Copyright © Editorial Office of Acta Mathematica Scientia
Add: P. O. Box 71010, Wuhan 430071, China Tel: 027-87199206(中文版) 027-87199087(英文版)
E-mail: actams@wipm.ac.cn