Dr Jerzy J. Jasielec

NPP for thin membranes

Nernst-Planck-Poisson Model for the description of electrodiffusion in thin membranes. It allows obtaining the potential and concentration profiles inside the membrane.

The Nernst-Planck equation relates the flux of ions to diffusion and migration processes and the Poisson equation describes the electric field occurring due to the movement of ions in the system. Software uses Chang-Jaffe boundary conditions for concentrations and Dirichlet boundary conditions for potential.

See the detailed description of the model

Begin with the input data for following system:

Input Data

Boundary conditions:

Number of ions in the system:

	Charge of ion z	Diffusion coefficient D [m²/s]	Concentration in the left solutionc_L [mol/m³]	Initial membrane concentrationc_M [mol/m³]	Concentration in the right solutionc_R [mol/m³]	Rate of entering the membranek_in [m/s]	Rate of leaving the membranek_out [m/s]
Ion 1
Ion 2
Ion 3
Ion 4
Ion 5
Ion 6

Potential at the left boundary		mV
Potential at the right boundary		mV

Duration of the process		s
Timestep

Width of the membrane		nm
Number of spatial points

Temperature		K
Dielectric permittivity		F/m

Calculations in progress:

Results

Dr Jerzy J. Jasielec

NPP for thin membranes

Nernst-Planck-Poisson Model for the description of electrodiffusion in thin membranes. It allows obtaining the potential and concentration profiles inside the membrane.

See the data values used in the plots