The ability to perform geometry optimizations on large molecular systems is desirable for both closed- and open-shell species. In this work, the restricted open-shell Hartree–Fock (ROHF) gradients for the fragment molecular orbital (FMO) method are presented. The accuracy of the gradients is tested, and the ability of the method to reproduce adiabatic excitation energies is also investigated. Timing comparisons between the FMO method and full ab initio calculations are also performed, demonstrating the efficiency of the FMO method in modeling large open-shell systems
The Z-vector equations are derived and implemented for solving the response term due to the external...
In this report, three versions of SCF/KS-DFT orbital optimization are described and benchmarked. The...
The frozen domain effective fragment molecular orbital method is extended to allow for the treatment...
The ability to perform geometry optimizations on large molecular systems is desirable for both close...
The fully analytic energy gradient has been developed and implemented for the restricted open-shell ...
The fully analytic energy gradient has been developed and implemented for the restricted open-shell ...
Performing accurate calculations on large molecular systems is desirable for closed- and open-shell ...
The fully analytic gradient is developed for density-functional tight-binding (DFTB) combined with t...
This work presents a procedure to optimize the molecular geometry at the Hartree-Fock level, based o...
The equations for the response terms for the fragment molecular orbital (FMO) method interfaced with...
A linear-scaling scheme for estimating the electronic energy, gradients, and Hessian of a large mole...
Three novel fragmentation methods that are available in the electronic structure program GAMESS (gen...
We present the use of the recently developed square gradient minimization (SGM) algorithm for excite...
We present a general approach to converge excited state solutions to any quantum chemistry orbital o...
Author Institution: Chemistry Division, Argonne National LaboratoryAn ab initio theory is presented ...
The Z-vector equations are derived and implemented for solving the response term due to the external...
In this report, three versions of SCF/KS-DFT orbital optimization are described and benchmarked. The...
The frozen domain effective fragment molecular orbital method is extended to allow for the treatment...
The ability to perform geometry optimizations on large molecular systems is desirable for both close...
The fully analytic energy gradient has been developed and implemented for the restricted open-shell ...
The fully analytic energy gradient has been developed and implemented for the restricted open-shell ...
Performing accurate calculations on large molecular systems is desirable for closed- and open-shell ...
The fully analytic gradient is developed for density-functional tight-binding (DFTB) combined with t...
This work presents a procedure to optimize the molecular geometry at the Hartree-Fock level, based o...
The equations for the response terms for the fragment molecular orbital (FMO) method interfaced with...
A linear-scaling scheme for estimating the electronic energy, gradients, and Hessian of a large mole...
Three novel fragmentation methods that are available in the electronic structure program GAMESS (gen...
We present the use of the recently developed square gradient minimization (SGM) algorithm for excite...
We present a general approach to converge excited state solutions to any quantum chemistry orbital o...
Author Institution: Chemistry Division, Argonne National LaboratoryAn ab initio theory is presented ...
The Z-vector equations are derived and implemented for solving the response term due to the external...
In this report, three versions of SCF/KS-DFT orbital optimization are described and benchmarked. The...
The frozen domain effective fragment molecular orbital method is extended to allow for the treatment...