Add to ORKGThe previously proposed atomic zeroth-order regular approximation (ZORA) approch, which was shown to eliminate the gauge dependent effect on gradients and to be remarkably accurate for geometry optimization, is tested for the calculation of analytical second derivatives. It is shown that the resulting analytic second derivatives are indeed exact within this approximation. The method proves to yield frequencies that are remarkably close to the experimental frequency for uranium hexafluoride but less satisfactory for the gold dimer
Second- and higher-order derivatives are required by applications in scientic computation, espe-cial...
and more accurate than the previously mentioned formulas. However, the computation of the Hessian ma...
Density functional theory (DFT) calculations of molecular hyperfine tensors were implemented as a se...
We discuss ways to obtain analytical gradients within the scalar zeroth-order regular approximation ...
A simple modification of the zeroth-order regular approximation (ZORA) in relativistic theory is sug...
By expanding the Foldy–Wouthuysen representation of the Dirac equation near the free-particle soluti...
In this paper we present the first application of the ZORA (Zeroth Order Regular Approximation of th...
In this paper we present the implementation of the two-component scaled zeroth-order regular approxi...
With the help of resolution of the identity (RI) a compact representation for the zeroth-order (ZORA...
The computation of nuclear second derivatives of energy, or the nuclear Hessian, is an essential rou...
The work herein is concerned with developing computational models to understand molecules. The under...
Modern methods for numerical optimization calculate (or approximate) the matrix of second derivative...
The development and computational implementation of analytical expres sions for the low-order deriv...
The zeroth-order regular approximation (ZORA) to the Dirac Hamiltonian and the Douglas-Kroll-Hess Ha...
The regular approximation to the normalized elimination of the small component (NESC) in the modifie...
Second- and higher-order derivatives are required by applications in scientic computation, espe-cial...
and more accurate than the previously mentioned formulas. However, the computation of the Hessian ma...
Density functional theory (DFT) calculations of molecular hyperfine tensors were implemented as a se...
We discuss ways to obtain analytical gradients within the scalar zeroth-order regular approximation ...
A simple modification of the zeroth-order regular approximation (ZORA) in relativistic theory is sug...
By expanding the Foldy–Wouthuysen representation of the Dirac equation near the free-particle soluti...
In this paper we present the first application of the ZORA (Zeroth Order Regular Approximation of th...
In this paper we present the implementation of the two-component scaled zeroth-order regular approxi...
With the help of resolution of the identity (RI) a compact representation for the zeroth-order (ZORA...
The computation of nuclear second derivatives of energy, or the nuclear Hessian, is an essential rou...
The work herein is concerned with developing computational models to understand molecules. The under...
Modern methods for numerical optimization calculate (or approximate) the matrix of second derivative...
The development and computational implementation of analytical expres sions for the low-order deriv...
The zeroth-order regular approximation (ZORA) to the Dirac Hamiltonian and the Douglas-Kroll-Hess Ha...
The regular approximation to the normalized elimination of the small component (NESC) in the modifie...
Second- and higher-order derivatives are required by applications in scientic computation, espe-cial...
and more accurate than the previously mentioned formulas. However, the computation of the Hessian ma...
Density functional theory (DFT) calculations of molecular hyperfine tensors were implemented as a se...