Genetic Exponentially Fitted Method for Solving Multi-dimensional Drift-diffusion Equations
Abstract
A general approach was proposed in this article to develop high-order exponentially fitted basis functions for finite element approximations of multi-dimensional drift-diffusion equations for modeling biomolecular electrodiffusion processes. Such methods are highly desirable for achieving numerical stability and efficiency. We found that by utilizing the one-one correspondence between continuous piecewise polynomial space of degree and the divergence-free vector space of degree , one can construct high-order 2-D exponentially fitted basis functions that are strictly interpolative at a selected node set but are discontinuous on edges in general, spanning nonconforming finite element spaces. First order convergence was proved for the methods constructed from divergence-free Raviart-Thomas space at two different node sets
Cite
@article{arxiv.1302.2668,
title = {Genetic Exponentially Fitted Method for Solving Multi-dimensional Drift-diffusion Equations},
author = {Melissa R. Swager and Y. C. Zhou},
journal= {arXiv preprint arXiv:1302.2668},
year = {2013}
}