Search results for "Molecular Electronic States"

showing 4 items of 4 documents

Nonadiabatic orientation, toroidal current, and induced magnetic field in BeO molecules.

2008

It is predicted that oriented BeO molecules would give rise to unprecedentedly strong, unidirectional electric ring current and an associated magnetic field upon excitation by a right or left circularly polarized laser pulse into the first excited degenerate singlet state. The strong toroidal electric ring current of this state is dominated by the ring current of the 1π± orbital about the molecular axis. Our predictions are based on the analysis of the orbital composition of the states involved and are substantiated by high level electronic structure calculations and wavepacket simulations of the laser-driven orientation and excitation dynamics. Luis.Serrano@uv.es

PhotoexcitationToroidMolecular electronic statesMolecule-photon collisionsMagnetic momentChemistryConfiguration interactionsExcited statesGeneral Physics and AstronomyElectronic structureMolecular orientationMagnetic fieldUNESCO::FÍSICA::Química físicaPhotoexcitationCoupled cluster calculationsBeryllium compoundsExcited stateMagnetic momentsPhysical and Theoretical ChemistryAtomic physics:FÍSICA::Química física [UNESCO]Beryllium compounds ; Configuration interactions ; Coupled cluster calculations ; Excited states ; Magnetic moments ; Molecular electronic states ; Molecular orientation ; Molecule-photon collisions ; PhotoexcitationRing currentExcitationThe Journal of chemical physics
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Reduced scaling in electronic structure calculations using Cholesky decompositions

2003

The small numerical rank of the two-electron integral matrix for large molecular systems and large basis sets was demonstrated. Though, the current implementation still requires some improvements on the calculations done in the inner most loop of the decomposition do not exploit the parsity in the Cholesky vectors. With respect to the practical applicability of the presented method an efficient approach to geometrical derivatives was imperative. Such an approach was obtained including certain derivative product functions and decomposing an expanded integral matrix.

PhysicsMolecular electronic statesMolecular electronic states ; Quantum chemistryIntegral matrixGeneral Physics and AstronomyElectronic structureQuantum chemistryUNESCO::FÍSICA::Química físicaPhysics and Astronomy (all)Computational chemistryFock matrixApplied mathematicsDensity fittingPhysical and Theoretical Chemistry:FÍSICA::Química física [UNESCO]ScalingQuantum chemistryCholesky decomposition
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Computation of conical intersections by using perturbation techniques

2005

Multiconfigurational second-order perturbation theory, both in its single-state multiconfigurational second-order perturbation theory (CASPT2) and multistate (MS-CASPT2) formulations, is used to search for minima on the crossing seams between different potential energy hypersurfaces of electronic states in several molecular systems. The performance of the procedures is tested and discussed, focusing on the problem of the nonorthogonality of the single-state perturbative solutions. In different cases the obtained structures and energy differences are compared with available complete active space self-consistent field and multireference configuration interaction solutions. Calculations on dif…

Potential Energy SurfacesConfiguration Interactions ; Perturbation Theory ; Potential Energy Surfaces ; Molecular Electronic States ; SCF Calculations ; Lithium Compounds ; Organic Compounds ; Wave FunctionsOrganic CompoundsChemistryComputationUNESCO::FÍSICAConfiguration InteractionsGeneral Physics and AstronomyMultireference configuration interactionConical surfaceSCF CalculationsPotential energyWave FunctionsMaxima and minima:FÍSICA [UNESCO]Molecular Electronic StatesQuantum mechanicsPerturbation TheoryLithium CompoundsStatistical physicsComplete active spacePerturbation theory (quantum mechanics)Physical and Theoretical ChemistryWave functionThe Journal of Chemical Physics
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A theoretical study of the gas-phase chemi-ionization reaction between uranium and oxygen atoms

2005

The U+O chemi-ionization reaction has been investigated by quantum chemical methods. Potential-energy curves have been calculated for several electronic states of UO and UO+. Comparison with the available spectroscopic and thermodynamic values for these species is reported and a mechanism for the chemi-ionization reaction U+O -> UO++e(-) is proposed. The U+O and Sm+O chemi-ionization reactions are the first two metal-plus-oxidant chemi-ionization reactions to be studied theoretically in this way.

Quantum chemicalMolecular electronic statesChemistryGeneral Physics and Astronomychemistry.chemical_elementUraniumOxygenElectronic statesGas phaseOxygenAtom-atom reactionsAssociative ionisationOxygen atomPotential energy surfacesIonizationddc:540Reaction kinetics theoryPhysics::Atomic and Molecular ClustersUraniumPhysical chemistryPhysics::Atomic PhysicsPhysical and Theoretical ChemistryNuclear ExperimentChain reactionUranium compoundsThe Journal of Chemical Physics
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