Co. KGaA, Weinheim)",
}
+@Article{zirkelbach14,
+ author = "F. Zirkelbach and P.-Y. Prodhomme and P. Han and R.
+ Cherian and G. Bester",
+ title = "Large-scale Atomic Effective Pseudopotential Program
+ ({LATEPP}) including an efficient spin-orbit coupling
+ treatment in real space",
+ journal = "to be published",
+ year = "2014",
+ abstract = "Within the scheme of the {\em Large-scale Atomic
+ Effective Pseudopotential Program}, the Schr{\"o}dinger
+ equation of an electronic system is solved within an
+ effective single-particle approach. Although not
+ limited to, it focuses on the recently introduced
+ atomic effective pseudopotentials derived from screened
+ local effective crystal potentials as obtained from
+ self-consistent density functional theory calculations.
+ Plane waves are used to expand the wavefunctions. The
+ problem can be solved in both, real and reciprocal
+ space. Using atomic effective pseudopotentials, a
+ self-consistency cycle is not required, which
+ drastically reduces the computational effort.
+ Furthermore, without having to find a self-consistent
+ solution, which would require the determination of all
+ eigenstates, iterative solvers can be used to focus
+ only on a few eigenstates in the vicinity of a
+ reference energy, e.g.\ around the band gap of a
+ semiconductor. Hence, this approach is particularly
+ well suited for theoretical investigations of the
+ electronic structure of semiconductor nanostructures
+ consisting of up to several thousands of atoms.
+ Moreover, a novel and efficient real space treatment of
+ spin-orbit coupling within the pseudopotential
+ framework is proposed in this work allowing for a fully
+ relativistic description.",
+}
+
@Article{lindner95,
author = "J. K. N. Lindner and A. Frohnwieser and B.
Rauschenbach and B. Stritzker",
projects / lectures / latex.git / commitdiff