Split-step spectral schemes for nonlinear Dirac systems
Journal of Computational Physics
Linearized Crank-Nicholson scheme for nonlinear Dirac equations
Journal of Computational Physics
Discretely nonreflecting boundary conditions for linear hyperbolic systems
Journal of Computational Physics
Fast Convolution for Nonreflecting Boundary Conditions
SIAM Journal on Scientific Computing
SIAM Journal on Numerical Analysis
Quantum dynamics of relativistic electrons
Journal of Computational Physics
Multi-symplectic Runge-Kutta methods for nonlinear Dirac equations
Journal of Computational Physics
Analysis of a leap-frog pseudospectral scheme for the Schrödinger equation
Journal of Computational and Applied Mathematics
An efficient adaptive mesh redistribution method for a non-linear Dirac equation
Journal of Computational Physics
Hi-index | 31.45 |
A finite difference scheme is presented for the Dirac equation in (1+1)D. It can handle space- and time-dependent mass and potential terms and utilizes exact discrete transparent boundary conditions (DTBCs). Based on a space- and time-staggered leap-frog scheme it avoids fermion doubling and preserves the dispersion relation of the continuum problem for mass zero (Weyl equation) exactly. Considering boundary regions, each with a constant mass and potential term, the associated DTBCs are derived by first applying this finite difference scheme and then using the Z-transform in the discrete time variable. The resulting constant coefficient difference equation in space can be solved exactly on each of the two semi-infinite exterior domains. Admitting only solutions in l"2 which vanish at infinity is equivalent to imposing outgoing boundary conditions. An inverse Z-transformation leads to exact DTBCs in form of a convolution in discrete time which suppress spurious reflections at the boundaries and enforce stability of the whole space-time scheme. An exactly preserved functional for the norm of the Dirac spinor on the staggered grid is presented. Simulations of Gaussian wave packets, leaving the computational domain without reflection, demonstrate the quality of the DTBCs numerically, as well as the importance of a faithful representation of the energy-momentum dispersion relation on a grid.