Search results for "Oppenheim"

showing 10 items of 15 documents

Quantum-chemical determination of Born–Oppenheimer breakdown parameters for rotational constants: the open-shell species CN, CO+ and BO

2013

The quantum-chemical protocol for computing Born-Oppenheimer breakdown corrections to rotational constants in the case of diatomic molecules is extended to open-shell species. The deviation from the Born-Oppenheimer equilibrium rotational constant is obtained by considering three contributions: the adiabatic correction to the equilibrium bond distance, the electronic contribution to the moment of inertia requiring the computation of the rotational g-tensor, and the so-called Dunham correction. Values for the Born-Oppenheimer breakdown parameters of CN, CO+, and BO in their (2)sigma(+) electronic ground states are reported based on coupled-cluster calculations of the involved quantities and …

AB INITIO CALCULATIONSChemistryBorn–Huang approximationBiophysicsBorn–Oppenheimer approximationRotational transitionRotational temperatureCondensed Matter PhysicsROTATIONAL CONSTANTSDiatomic moleculesymbols.namesakesymbolsBorn-Oppenheimer breakdown correctionRotational spectroscopyPhysics::Chemical PhysicsPhysical and Theoretical ChemistryAtomic physicsRotational partition functionMolecular BiologyOpen shellMolecular Physics
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Many-body Green's function theory of electrons and nuclei beyond the Born-Oppenheimer approximation

2020

The method of many-body Green's functions is developed for arbitrary systems of electrons and nuclei starting from the full (beyond Born-Oppenheimer) Hamiltonian of Coulomb interactions and kinetic energies. The theory presented here resolves the problems arising from the translational and rotational invariance of this Hamiltonian that afflict the existing many-body Green's function theories. We derive a coupled set of exact equations for the electronic and nuclear Green's functions and provide a systematic way to approximately compute the properties of arbitrary many-body systems of electrons and nuclei beyond the Born-Oppenheimer approximation. The case of crystalline solids is discussed …

Born–Oppenheimer approximationFOS: Physical sciences02 engineering and technologyElectronKinetic energy01 natural sciencesMany bodytiiviin aineen fysiikkaGreen's function methodssymbols.namesake0103 physical sciencesCoulombkvanttifysiikka010306 general physicsPhysicsQuantum PhysicsExact differential equation021001 nanoscience & nanotechnologyMany-body techniquesCondensed Matter - Other Condensed MatterClassical mechanicssymbolsRotational invarianceCrystalline systemsapproksimointiQuantum Physics (quant-ph)0210 nano-technologyHamiltonian (quantum mechanics)Other Condensed Matter (cond-mat.other)
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Surrealismo e dintorni

2010

CarringtonSurfantaCirlotAvanguardia - Surrealismo - Breton - DubuffetDubuffetTanningArt BrutDaliWeiss.PaladiniSurrealismo Art Brut Carrington Cirlot Dali Dubuffet Lorca Oppenheim Paladini Rozda Surfanta Tanning Tatin Weiss.RozdaLorcaOppenheimSettore L-ART/03 - Storia Dell'Arte ContemporaneaTatinSurrealismo
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Analytic calculation of the diagonal Born-Oppenheimer correction within configuration-interaction and coupled-cluster theory

2006

Schemes for the analytic calculation of the diagonal Born-Oppenheimer correction (DBOC) are formulated and implemented for use with general single-reference configuration-interaction and coupled-cluster wave function models. Calculations are reported to demonstrate the convergence of the DBOC with respect to electron-correlation treatment and basis set as well as to investigate the size-consistency error in configuration-interaction calculations of the DBOC. The importance of electron-correlation contributions to the DBOC is illustrated in the computation of the corresponding corrections for the reaction energy and activation barrier of the F + H2 --FH + H reaction as well as of the atomiza…

ChemistryComputationDiagonalBorn–Oppenheimer approximationGeneral Physics and AstronomyConfiguration interactionsymbols.namesakeCoupled clusterQuantum electrodynamicsConvergence (routing)symbolsPhysical and Theoretical ChemistryAtomic physicsWave functionBasis setThe Journal of Chemical Physics
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High-accuracy extrapolated ab initio thermochemistry. III. Additional improvements and overview

2008

Effects of increased basis-set size as well as a correlated treatment of the diagonal Born-Oppenheimer approximation are studied within the context of the high-accuracy extrapolated ab initio thermochemistry (HEAT) theoretical model chemistry. It is found that the addition of these ostensible improvements does little to increase the overall accuracy of HEAT for the determination of molecular atomization energies. Fortuitous cancellation of high-level effects is shown to give the overall HEAT strategy an accuracy that is, in fact, higher than most of its individual components. In addition, the issue of core-valence electron correlation separation is explored; it is found that approximate add…

Electronic correlationChemistryBorn–Oppenheimer approximationAb initioGeneral Physics and AstronomyThermodynamicsContext (language use)symbols.namesakeChemical thermodynamicsComputational chemistryAb initio quantum chemistry methodsThermochemistrysymbolsPhysical and Theoretical ChemistryThe Journal of Chemical Physics
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Quantum-chemical calculation of Born–Oppenheimer breakdown parameters to rotational constants

2010

The paper describes how Born–Oppenheimer breakdown parameters for the rotational constants of diatomic molecules can be determined via quantum-chemical computations. The deviations from the Born–Oppenheimer equilibrium values are accounted for by considering the adiabatic correction to the equilibrium bond distances, the electronic contribution to the rotational constant via the rotational g tensor, and the so-called Dunham correction, which can be computed directly from a polynomial expansion of the potential curve around the equilibrium distance. Calculations for HCl, SiS, and HF demonstrate the accuracy that can be achieved in the theoretical treatment of the considered Born–Oppenheimer …

Field (physics)ChemistryBiophysicsBorn–Oppenheimer approximationRotational transitionRotational temperatureCondensed Matter PhysicsDiatomic moleculesymbols.namesakesymbolsRotational spectroscopyPhysics::Chemical PhysicsPhysical and Theoretical ChemistryAtomic physicsRotational partition functionAdiabatic processMolecular BiologyMolecular Physics
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Spheroidal and hyperspheroidal coordinates in the adiabatic representation of scattering states for the Coulomb three-body problem

2009

Recently, an involved approach has been used by Abramov (2008 J. Phys. B: At. Mol. Opt. Phys. 41 175201) to introduce a separable adiabatic basis into the hyperradial adiabatic (HA) approximation. The aim was to combine the separability of the Born–Oppenheimer (BO) adiabatic basis and the better asymptotic properties of the HA approach. Generalizing these results we present here three more different separable bases of the same type by making use of a previously introduced adiabatic Hamiltonian expressed in hyperspheroidal coordinates (Matveenko 1983 Phys. Lett. B 129 11). In addition, we propose a robust procedure which accounts in a stepwise procedure for the unphysical couplings that are …

PhysicsBorn–Oppenheimer approximationCondensed Matter PhysicsThree-body problemAdiabatic quantum computationAtomic and Molecular Physics and OpticsMathematical OperatorsAdiabatic theoremMany-body problemsymbols.namesakeQuantum mechanicssymbolsAdiabatic processHamiltonian (quantum mechanics)Journal of Physics B: Atomic, Molecular and Optical Physics
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Self-consistent field theory based molecular dynamics with linear system-size scaling

2012

We present an improved field-theoretic approach to the grand-canonical potential suitable for linear scaling molecular dynamics simulations using forces from self-consistent electronic structure calculations. It is based on an exact decomposition of the grand canonical potential for independent fermions and does neither rely on the ability to localize the orbitals nor that the Hamilton operator is well-conditioned. Hence, this scheme enables highly accurate all-electron linear scaling calculations even for metallic systems. The inherent energy drift of Born-Oppenheimer molecular dynamics simulations, arising from an incomplete convergence of the self-consistent field cycle, is circumvented …

PhysicsChemical Physics (physics.chem-ph)Condensed Matter - Materials ScienceField (physics)Linear systemBorn–Oppenheimer approximationGeneral Physics and AstronomyMaterials Science (cond-mat.mtrl-sci)FOS: Physical sciencesComputational Physics (physics.comp-ph)Langevin equationMolecular dynamicssymbols.namesakePhysics - Chemical PhysicssymbolsLinear scaleEnergy driftStatistical physicsPhysical and Theoretical ChemistryPhysics - Computational PhysicsScaling
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Perturbative treatment of the electron-correlation contribution to the diagonal Born-Oppenheimer correction.

2007

A perturbative scheme for the treatment of electron-correlation effects on the diagonal Born-Oppenheimer correction (DBOC) is suggested. Utilizing the usual Moller-Plesset partitioning of the Hamiltonian formulas for first and second orders (termed as MP1 and MP2) are obtained by expanding the wave function in the corresponding coupled-cluster expressions for the DBOC[J. Gauss et al., J. Chem. Phys. 125, 144111 (2006)]. The obtained expressions are recast in terms of one- and two-particle density matrices in order to take advantage of existing analytic second-derivative implementations for many-body methods. Test calculations show that both MP1 and MP2 recover large fractions (on average 90…

PhysicsElectronic correlationGaussDiagonalBorn–Oppenheimer approximationGeneral Physics and Astronomysymbols.namesakeCoupled clusterQuantum mechanicsPhysics::Atomic and Molecular ClusterssymbolsPerturbation theory (quantum mechanics)Physical and Theoretical ChemistryHamiltonian (quantum mechanics)Wave functionThe Journal of chemical physics
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Dynamics of H2 molecule driven by an ultra-short laser field

2004

We describe, using a semiclassical approach, the molecular dynamics of a one-dimensional H2 molecule interacting with a laser, beyond the Born–Oppenheimer approximation. We observe and discuss different molecular behaviors, such as ionization and dissociation.

PhysicsQuantum opticsPhysics and Astronomy (miscellaneous)Harmonic generationGeneral EngineeringBorn–Oppenheimer approximationhigh-order-harmonic generationGeneral Physics and AstronomySemiclassical physicsPhotoionizationLaserSettore FIS/03 - Fisica Della Materialaw.inventionMolecular dynamicssymbols.namesakelawIonizationPhysics::Atomic and Molecular ClusterssymbolsMoleculePhysics::Chemical PhysicsAtomic physicsharmonic generations
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