A decoupled algorithm for a drift-diffusion model

In this paper, we derive a coupled Schrödinger drift-diffusion self-consistent stationary model for quantum semiconductor device simulations. The device is decomposed into a quantum zone (where quantum effects are expected to be large) and a classical zone (where they are supposed negligible). The S

The limit of the vanishing Debye length (the charge neutral limit) in a nonlinear bipolar drift-diffusion model for semiconductors without a pn-junction (i.e., with a unipolar background charge) is studied. The quasi-neutral limit 1 Supported by the EU-funded TMR-network Asymptotic Methods in Kineti

Adiabatic decoupling is as dependent on well-designed inversion pulse can be a sizable fraction of 1/J. However, phase cycles for performance as any broadband method. pulse length and RF field strength can be varied indepen-For example, the dramatic performance gains of STUD (1) dently in adiabatic

We have developed a three-dimensional anisotropic multigrid solver for simulating nonlocal collisional electrostatic drift-wave turbulence in a tokamak with magnetic shear. As an example, the solver has been used to obtain entire flux-surface solutions of the nonlocal Hasegawa-Wakatani equations in