Abstract
In this work, we present a fully automated method
for the construction of chemically meaningful sets of non-redundant
internal coordinates (also commonly denoted as Z-matrices)
from the cartesian coordinates of a molecular system.
Particular focus is placed on avoiding ill-definitions
of angles and dihedrals due to linear arrangements of atoms,
to consistently guarantee a well-defined transformation
to cartesian coordinates, even after structural changes.
The representations thus obtained are particularly well suited for
pathway construction in double-ended methods for transition state search and
optimisations with non-linear constraints.
Analytical gradients for the transformation between
the coordinate systems were derived for the first time,
which allows analytical geometry optimizations purely in Z-matrix coordinates.
The geometry optimisation was coupled with
a Symbolic Algebra package to support arbitrary non-linear constraints
in Z-matrix coordinates, while retaining analytical energy gradient conversion.
Sample applications are provided for a number of common chemical
reactions and illustrative examples where these new algorithms
can be used to automatically produce chemically reasonable structure interpolations,
or to perform non-linearly constrained optimisations of molecules.
Supplementary materials
Title
Supporting Information
Description
The Supporting Information contains an example for a failing conversion between Cartesian and Z-matrix coordinates, and the analytical derivatives of the basis $\vb{B}$.
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