We analyze and benchmark the error and the convergence order of finite difference, finite-element as well as Voronoi finite-volume discretization schemes for the drift-diffusion equations describing charge transport in bulk semiconductor devices. Three common challenges, that can corrupt the precision of numerical solutions, will be discussed: boundary layers at Ohmic contacts, discontinuties in the doping profile, and corner singularities in L-shaped domains. The influence on the order of convergence is assessed for each computational challenge and the different discretization schemes. Additionally, we provide an analysis of the inner boundary layer asymptotics near Ohmic contacts to support our observations
We introduce a family of two point flux expressions for charge carrier transport described by d...
Since the 1950s, semiconductors have played a significant and daily role in our lives, as they are t...
We regard drift-diffusion equations for semiconductor devices in Lebesgue spaces. To that end we re...
We study different discretizations of the van Roosbroeck system for charge transport in bulk semicon...
The van Roosbroeck system describes the semi-classical transport of free electrons and holes in a se...
We present charge transport models for novel semiconductor devices which may include ionic species a...
For a Voronoï finite volume discretization of the van Roosbroeck system with general charge carrier ...
This is a collection of data files, used in the publication Challenges for drift-diffusion simulatio...
The van Roosbroeck system models current flows in (non-)degenerate semiconductor devices. Focusing o...
This paper contains an overview on numerical schemes for some of the most widely used fluid models ...
In this paper, optimal error estimates are obtained for a method for numerically solving the so-call...
The Drift Diffusion equations constitute the simplest and most commonly used model for simulating se...
AbstractWe study nonlinear finite element discretizations for the density gradient equation in the q...
We regard drift-diffusion equations for semiconductor devices in Lebesgue spaces. To that end we ref...
This work focuses on some of the most relevant numerical issues in the solution of the drift-diffusi...
We introduce a family of two point flux expressions for charge carrier transport described by d...
Since the 1950s, semiconductors have played a significant and daily role in our lives, as they are t...
We regard drift-diffusion equations for semiconductor devices in Lebesgue spaces. To that end we re...
We study different discretizations of the van Roosbroeck system for charge transport in bulk semicon...
The van Roosbroeck system describes the semi-classical transport of free electrons and holes in a se...
We present charge transport models for novel semiconductor devices which may include ionic species a...
For a Voronoï finite volume discretization of the van Roosbroeck system with general charge carrier ...
This is a collection of data files, used in the publication Challenges for drift-diffusion simulatio...
The van Roosbroeck system models current flows in (non-)degenerate semiconductor devices. Focusing o...
This paper contains an overview on numerical schemes for some of the most widely used fluid models ...
In this paper, optimal error estimates are obtained for a method for numerically solving the so-call...
The Drift Diffusion equations constitute the simplest and most commonly used model for simulating se...
AbstractWe study nonlinear finite element discretizations for the density gradient equation in the q...
We regard drift-diffusion equations for semiconductor devices in Lebesgue spaces. To that end we ref...
This work focuses on some of the most relevant numerical issues in the solution of the drift-diffusi...
We introduce a family of two point flux expressions for charge carrier transport described by d...
Since the 1950s, semiconductors have played a significant and daily role in our lives, as they are t...
We regard drift-diffusion equations for semiconductor devices in Lebesgue spaces. To that end we re...