We demonstrate how quantum chemical Hartree-Fock (HF) or density functional theory (DFT) optimizations with small basis sets of peptide and water cluster structures are decisively improved if London-dispersion effects, the basis-set-superposition error (BSSE), and other basis-set incompleteness errors are addressed. We concentrate on three empirical corrections to these problems advanced by Grimme and co-workers that lead to computational strategies that are both accurate and efficient. Our analysis encompasses a reoptimized version of Hobza's P26 set of tripeptide structures, a new test set of conformers of cysteine dimers, and isomers of the water hexamer. These systems reflect features commonly found in protein crystal structures. In all...
Knowledge of the atomic structure of biomolecules, such as proteins, is paramount to understanding t...
Ranking the binding of small molecules to protein receptors through physics-based computation remain...
The ability to calculate accurate electron densities of full proteins or of selected sites in protei...
We demonstrate how quantum chemical Hartree–Fock (HF) or density functional theory (DFT) optimizatio...
We demonstrate the importance of properly accounting for London dispersion and basis-set-superpositi...
Recent algorithmic and hardware advances have enabled the application of electronic structure method...
Density functional theory (DFT) has become a routine tool for the computation of electronic structur...
ABSTRACT: Structural properties of over 55 small proteins have been determined using both density-ba...
Short hydrogen bonds (SHBs), which have the donor and acceptor separations below 2.7 Å, occur widely...
We extend to strongly correlated molecular systems the recently introduced basis-set incompleteness ...
We have re-refined the X-ray structure of the heme site in cytochrome c553, supplementing the crysta...
The accurate prediction of protein–ligand binding free energies with tractable computational methods...
We present an extension of the frozen-density embedding (FDE) scheme within density-functional theor...
Accurately computing the geometry and energy of host–guest and protein–ligand interactions requires ...
It has been demonstrated that the fragmentation scheme of our adjustable density matrix assembler (A...
Knowledge of the atomic structure of biomolecules, such as proteins, is paramount to understanding t...
Ranking the binding of small molecules to protein receptors through physics-based computation remain...
The ability to calculate accurate electron densities of full proteins or of selected sites in protei...
We demonstrate how quantum chemical Hartree–Fock (HF) or density functional theory (DFT) optimizatio...
We demonstrate the importance of properly accounting for London dispersion and basis-set-superpositi...
Recent algorithmic and hardware advances have enabled the application of electronic structure method...
Density functional theory (DFT) has become a routine tool for the computation of electronic structur...
ABSTRACT: Structural properties of over 55 small proteins have been determined using both density-ba...
Short hydrogen bonds (SHBs), which have the donor and acceptor separations below 2.7 Å, occur widely...
We extend to strongly correlated molecular systems the recently introduced basis-set incompleteness ...
We have re-refined the X-ray structure of the heme site in cytochrome c553, supplementing the crysta...
The accurate prediction of protein–ligand binding free energies with tractable computational methods...
We present an extension of the frozen-density embedding (FDE) scheme within density-functional theor...
Accurately computing the geometry and energy of host–guest and protein–ligand interactions requires ...
It has been demonstrated that the fragmentation scheme of our adjustable density matrix assembler (A...
Knowledge of the atomic structure of biomolecules, such as proteins, is paramount to understanding t...
Ranking the binding of small molecules to protein receptors through physics-based computation remain...
The ability to calculate accurate electron densities of full proteins or of selected sites in protei...