Galerkin Methods for Boltzmann-Poisson transport with reflection conditions on rough boundaries
This work addresses the need for accurate boundary condition modeling in nanoscale semiconductor simulations, but the contribution is incremental as it extends existing DG methods to include more realistic reflection models.
The paper develops numerical methods for reflective boundary conditions in Boltzmann-Poisson transport models for nanoscale semiconductor devices, implementing diffusive and specular reflection in a Discontinuous Galerkin scheme. Results show that diffusive conditions affect kinetic moments across the entire spatial domain.
We consider in this paper the mathematical and numerical modelling of reflective boundary conditions (BC) associated to Boltzmann - Poisson systems, including diffusive reflection in addition to specularity, in the context of electron transport in semiconductor device modelling at nano scales, and their implementation in Discontinuous Galerkin (DG) schemes. We study these BC on the physical boundaries of the device and develop a numerical approximation to model an insulating boundary condition, or equivalently, a pointwise zero flux mathematical condition for the electron transport equation. Such condition balances the incident and reflective momentum flux at the microscopic level, pointwise at the boundary, in the case of a more general mixed reflection with momentum dependant specularity probability $p(\vec{k})$. We compare the computational prediction of physical observables given by the numerical implementation of these different reflection conditions in our DG scheme for BP models, and observe that the diffusive condition influences the kinetic moments over the whole domain in position space.