An Explicit Quantum Chemical Method for Modeling Large Solvation Shells Applied to Aminocoumarin C151

Neugebauer, Johannes; Jacob, Christoph R.; Wesołowski, Tomasz Adam; Baerends, Evert Jan

doi:10.1021/jp0528764

Cited by 150 publications

(253 citation statements)

References 53 publications

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“…For dipole-bound complexes, the errors in the binding energy are larger. The maximal relative overestimation of the binding energy for HCN-CH 3 SH reaches 30%, whereas the binding energy in CH 3 ClHCl is underestimated by 19%. For van der Waals complexes, KSCED LDA does not perform uniformly.…”

Section: Geometries: Ldamentioning

confidence: 93%

Equilibrium Geometries of Noncovalently Bound Intermolecular Complexes Derived from Subsystem Formulation of Density Functional Theory

Dułak

Kaminski

Wesołowski

2007

J. Chem. Theory Comput.

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Abstract:The subsystem formulation of density functional theory is used to obtain equilibrium geometries and interaction energies for a representative set of noncovalently bound intermolecular complexes. The results are compared with literature benchmark data. The range of applicability of two considered approximations to the exchange-correlation-and nonadditive kinetic energy components of the total energy is determined. Local density approximation, which does not involve any empirical parameters, leads to excellent intermolecular equilibrium distances for hydrogen-bonded complexes (maximal error 0.13 Å for NH 3 -NH 3 ). It is a method of choice for a wide class of weak intermolecular complexes including also dipole-bound and the ones formed by rare gas atoms or saturated hydrocarbons. The range of applicability of the chosen generalized gradient approximation, which was shown in our previous works to lead to good interaction energies in such complexes, where π-electrons are involved in the interaction, remains limited to this group because it improves neither binding energies nor equilibrium geometries in the wide class of complexes for which local density approximation is adequate. An efficient energy minimization procedure, in which optimization of the geometry and the electron density of each subsystem is made simultaneously, is proposed and tested.

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Section: Geometries: Ldamentioning

confidence: 93%

Equilibrium Geometries of Noncovalently Bound Intermolecular Complexes Derived from Subsystem Formulation of Density Functional Theory

Dułak

Kaminski

Wesołowski

2007

J. Chem. Theory Comput.

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“…The new results object is then used to initialize and run an adfnmrjob (lines [24][25][26]. Finally, the get_all_shieldings method of the NMR job's results object is used to extract the calculated shieldings, which can then be printed (lines [28][29][30][31].…”

Section: A Simple Example: Calculation Of Nmr Shieldingsmentioning

confidence: 99%

“…An important multiscale application of the FDE scheme is the calculation of solvent effects on molecular properties (e.g., electronic excitation energies, 29,30 ESR hyperfine coupling constants, 53 or NMR shieldings 31 ). Such calculations employ the sequential molecular dynamics followed by quantum-mechanics calculations (S-MD/QM) strategy.…”

Section: Solvent Effects On Molecular Propertiesmentioning

confidence: 99%

“…Typically, they involve hundreds of individual calculations, and the results of a subset of these calculations are needed as input for following steps. For instance, applications of the FDE scheme to calculate solvent effects on molecular properties [29][30][31] require the construction of an approximate solvent electron density, followed by an FDE calculation of the molecular property of interest for the embedded solute molecule. This needs to be done for a large number of snapshots taken from a molecular dynamics simulation.…”

Section: Introductionmentioning

confidence: 99%

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PyADF — A scripting framework for multiscale quantum chemistry

Jacob

Beyhan²,

Bulo³

et al. 2011

J Comput Chem

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101

106

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Abstract:Applications of quantum chemistry have evolved from single or a few calculations to more complicated workflows, in which a series of interrelated computational tasks is performed. In particular multiscale simulations, which combine different levels of accuracy, typically require a large number of individual calculations that depend on each other. Consequently, there is a need to automate such workflows. For this purpose we have developed PyAdf, a scripting framework for quantum chemistry. PyAdf handles all steps necessary in a typical workflow in quantum chemistry and is easily extensible due to its object-oriented implementation in the Python programming language. We give an overview of the capabilities of PyAdf and illustrate its usefulness in quantum-chemical multiscale simulations with a number of examples taken from recent applications.

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“…Absorption spectra of aminocoumarin c151 in water (black) and n-hexane (red) obtained form multi-level simulations using orbital-free embedding potential to couple the solvent with the chromophore. [46] 4 , a compound dense in uranium and nitrogen, which can be used as a molecular precursor to high-purity UN, a potential nuclear fuel of the future.…”

Section: Computational Chemistry At the Dpcmentioning

confidence: 99%