The computation of vibrational spectra of diatomic molecules through the exact diagonalization of algebraically determined matrices based on powers of Morse coordinates is made substantially more efficient by choosing a properly adapted quantum mechanical basis, specifically tuned to the molecular potential. A substantial improvement is achieved while still retaining the full advantage of the simplicity and numerical light-weightedness of an algebraic approach. In the scheme we propose, the basis is parametrized by two quantities which can be adjusted to best suit the molecular potential through a simple minimization procedure
I review some computational methods for calculating vibrational spectra. They all use iterative eige...
This work explores the use of the eigenfunctions of the Morse potential with a infinite barrier at l...
We present full-dimensional quantum mechanical calculations of the vibrational states of acetylene. ...
We propose an accurate and efficient method to compute vibrational spectra of molecules, based on ...
I shall present an improvement and applications of the Hierarchical Intertwined Reduced-Rank Blo...
_x000d_ I shall present two new variational methods for computing vibrational spectra. Both rely o...
We introduce an accurate and efficient algebraic technique for the computation of the vibrational sp...
A number of potentials have been suggested as approximations to the 'true' potential function for th...
The memory cost of representing vibrational wavefunctions of polyatomic molecules with more than 6 a...
International audienceWe present a new basis set as an alternative to Legendre polynomials for the v...
A numerical application of linear-molecule symmetry properties, described by the D ∞ h ...
The construction of molecular mechanics potential energy functions is discussed from the viewpoint o...
First the salient features of the $U(\nu+1)$ algebraic approach associated to $\nu$ equivalent osci...
Numerical atomic basis orbitals are variationally optimized for biological molecules such as protein...
Author Institution: Laboratory of Molecular Spectroscopy, Czechoslovak Academy of Sciences; Laborato...
I review some computational methods for calculating vibrational spectra. They all use iterative eige...
This work explores the use of the eigenfunctions of the Morse potential with a infinite barrier at l...
We present full-dimensional quantum mechanical calculations of the vibrational states of acetylene. ...
We propose an accurate and efficient method to compute vibrational spectra of molecules, based on ...
I shall present an improvement and applications of the Hierarchical Intertwined Reduced-Rank Blo...
_x000d_ I shall present two new variational methods for computing vibrational spectra. Both rely o...
We introduce an accurate and efficient algebraic technique for the computation of the vibrational sp...
A number of potentials have been suggested as approximations to the 'true' potential function for th...
The memory cost of representing vibrational wavefunctions of polyatomic molecules with more than 6 a...
International audienceWe present a new basis set as an alternative to Legendre polynomials for the v...
A numerical application of linear-molecule symmetry properties, described by the D ∞ h ...
The construction of molecular mechanics potential energy functions is discussed from the viewpoint o...
First the salient features of the $U(\nu+1)$ algebraic approach associated to $\nu$ equivalent osci...
Numerical atomic basis orbitals are variationally optimized for biological molecules such as protein...
Author Institution: Laboratory of Molecular Spectroscopy, Czechoslovak Academy of Sciences; Laborato...
I review some computational methods for calculating vibrational spectra. They all use iterative eige...
This work explores the use of the eigenfunctions of the Morse potential with a infinite barrier at l...
We present full-dimensional quantum mechanical calculations of the vibrational states of acetylene. ...