Analytic derivatives of potential energy surface

Tozer, David James

January 1994

No description available.

530.41

Quantum chemistry

The perturbative treatment of electron correlation

Andrews, Jamie Stuart

January 1992

No description available.

539.7

Quantum chemistry

Molecular property surfaces

Jayatilaka, Dylan

January 1991

No description available.

539.7

Quantum chemistry

Analytic derivatives using correlated wavefunctions

Alberts, Ian Lee

January 1988

No description available.

530.1

Quantum chemistry

Induction effects in Van der Waals complexes

Le Sueur, Catherine Ruth

January 1990

No description available.

541

Quantum chemistry

A modern valence bond study of charge-transfer processes of astrophysical interest

Turner, Andrew Robert

January 2002

No description available.

541

Quantum chemistry

Size-extensive electronic structure theories : methodologies and applications

Deegan, Miles

January 1994

No description available.

539.7

Quantum chemistry

Novel stochastic approaches in molecular quantum mechanics

Thomas, Robert Edward

January 2015

No description available.

540

Quantum chemistry

The stability of small atoms and molecules : a quantum mechanical three-body study

King, Andrew

January 2016

Three-body systems provide the perfect framework for studying the quantum mechanics of both atoms and molecules. These studies can probe the fundamentals of particle interactions that underpin stability, reactivity and structure. This thesis contains a series of studies into the stability of ground state three-body systems. The focus of this thesis has been the high accuracy computation of three-body systems without recourse to either the Born-Oppenheimer (BO) approximationor approximation of the like-charged particle interaction, which for the case of atoms corresponds to the electron correlation. Principally the effects of mass and charge on the stability of systems is predicted. The complex nature of coupled electronic interaction is studied to the purpose of pursuing accurate electron correlation that underpins modern computational chemistry. The energies of three-body systems were calculated very accurately to typically mJ mol-1 accuracy or better whilst still producing reliable wavefunctions of which all other properties of the system could be calculated accurately. The energies of some of these systems are the lowest to date and all use the latest finite masses as published by CODATA. Computational codes were developed to achieve this accuracy using both numerical and computer algebra methods. These were designed to be efficient, extendable and, importantly, to calculate highly accurate energies, expectation values and wave functions. The masses of any three particles in which there exists at least one bound state below the lowest continuum threshold were identified. The importance of symmetry breaking in a asymmetric system was made clear as the difference in the masses become larger. A new method was developed to identify the lowest charge of a nucleus that can bind two electrons. This method is more effective then those previously available as it produces a variational upper bound to the true minimum charge in a single calculation. The method was employed to identify the minimum nuclear charge required for binding two electrons in atoms of various nuclear masses. Additionally the electronic structure of such systems was investigated by a judicious partitioning that separates the two electrons into an inner and outer component relative to the nucleus. The electron correlation was calculated using the Löwdin definition and a highly accurate Hartree-Fock (HF) implementation specifically designed for the task. The effects this electron correlation has on various properties was quantified including the coulomb hole. A second coulomb hole was found which was previously thought to be an artefact but remains even with this highly accurate implementation.

540

QD0462 Quantum chemistry

Electronic properties of molecules

Bearpark, Michael John

January 1993

No description available.

541

Quantum chemistry