D. Van Neck

The Gradient Curves Method:  An Improved Strategy for the Derivation of Molecular Mechanics Valence Force Fields from ab Initio Data

T. Verstraelen, D. Van Neck, P.W. Ayers, V. Van Speybroeck, M. Waroquier
Journal of Chemical Theory and Computation (JCTC)
3 (4), 1420–1434
2007
A1

Abstract 

A novel force-field development strategy is proposed that tackles the well-known difficulty of parameter correlations arising in a conventional least-squares optimization. In the first step of the new gradient curves method (GCM), continuity criteria are imposed to transform the raw multidimensional ab initio training data to distinct sets of one-dimensional data, each associated with an individual energy term. In the second step, the transformed data suggest suitable analytical expressions, and the parameters in these expressions are fitted to the transformed data; that is, one does not have to postulate a priori analytical expressions for the force-field energy terms. This approach facilitates the derivation of valence terms. Benchmarks have been performed on a set of small molecules. The results show that the new method yields physically acceptable energy terms exactly when a conventional parametrization would suffer from parameter correlations, that is, when an increasing number of redundant internal coordinates is used in the force-field model. The generic treatment of parameter correlations in the proposed method facilitates an intuitive physical interpretation of the individual terms in the force-field expression, which is a prerequisite for the transferability of force-field models.

Vibrational Modes in partially optimized molecular systems

A. Ghysels, D. Van Neck, V. Van Speybroeck, T. Verstraelen, M. Waroquier
Journal of Chemical Physics
126 (22), 224102
2007
A1

Abstract 

In this paper the authors develop a method to accurately calculate localized vibrational modes for partially optimized molecular structures or for structures containing link atoms. The method avoids artificially introduced imaginary frequencies and keeps track of the invariance under global translations and rotations. Only a subblock of the Hessian matrix has to be constructed and diagonalized, leading to a serious reduction of the computational time for the frequency analysis. The mobile block Hessian approach (MBH) proposed in this work can be regarded as an extension of the partial Hessian vibrational analysis approach proposed by Head [Int. J. Quantum Chem. 65, 827 (1997)] . Instead of giving the nonoptimized region of the system an infinite mass, it is allowed to move as a rigid body with respect to the optimized region of the system. The MBH approach is then extended to the case where several parts of the molecule can move as independent multiple rigid blocks in combination with single atoms. The merits of both models are extensively tested on ethanol and di-n-octyl-ether.

Characterization of the electron propagator with a GW-like self-energy in closed-shell atoms

S. Verdonck, D. Van Neck, P.W. Ayers, M. Waroquier
Physical Review A
74 (6), 062503
2006
A1

Abstract 

The electron propagator is calculated for a set of closed-shell atoms using GW-like self-energies that contain the coupling of single-particle degrees of freedom with excited states in the framework of the random phase approximation. The effect of including exchange diagrams is investigated. Calculations are performed in the Hartree-Fock (HF) basis of the neutral atom. The HF continuum is taken into account using a discretization procedure, and the basis set limit is estimated using a systematic increase of basis set size. We check the approximation of taking the self-energy diagonal in the HF basis, and to what extent the extended Koopman’s theorem is fulfilled using an approximate self-energy. Finally we try to model the information contained in the propagator in terms of a functional containing Hartree-Fock quantities and demonstrate the feasibility of simultaneously reproducing the correlation and ionization energy of an underlying ab initio model.

Quasiparticle properties in a density-functional framework

D. Van Neck, S. Verdonck, G. Bonny, P.W. Ayers, M. Waroquier
Physical Review A
74 (4), 042501
2006
A1

Abstract 

We propose a framework to construct the ground-state energy and density matrix of an N-electron system by solving a self-consistent set of single-particle equations. The method can be viewed as a nontrivial extension of the Kohn-Sham scheme (which is embedded as a special case). It is based on separating the Green’s function into a quasiparticle part and a background part, and expressing only the background part as a functional of the density matrix. The calculated single-particle energies and wave functions have a clear physical interpretation as quasiparticle energies and orbitals.

An extended hindered-rotor model with incorporation of Coriolis and vibrational-rotational coupling for calculating partition functions and derived quantities

P. Vansteenkiste, V. Van Speybroeck, D. Van Neck, M. Waroquier
Journal of Chemical Physics
124 (4), 044314
2006
A1

Abstract 

Large-amplitude motions, particularly internal rotations, are known to affect substantially thermodynamic functions and rate constants of reactions in which flexible molecules are involved. Up to now all methods for computing the partition functions of these motions rely on the Pitzer approximation of more than 50 years ago, in which the large-amplitude motion is treated in complete independence of the other (vibrational) degrees of freedom. In this paper an extended hindered-rotor model (EHR) is developed in which the vibrational modes, treated harmonically, are correctly separated from the large-amplitude motion and in which relaxation effects (the changes in the kinetic-energy matrix and potential curvature) are taken into account as one moves along the large-amplitude path. The model also relies on a specific coordinate system in which the Coriolis terms vanish at all times in the Hamiltonian. In this way an increased level of consistency between the various internal modes is achieved, as compared with the more usual hindered-rotor (HR) description. The method is illustrated by calculating the entropies and heat capacities on 1,3-butadiene and 1-butene (with, respectively, one and two internal rotors) and the rate constant for the addition reaction of a vinyl radical to ethene. We also discuss various variants of the one-dimensional hindered-rotor scheme existing in the literature and its relation with the EHR model. It is argued why in most cases the HR approach is already quite successful.

Spectral functions in an exactly solvable self-bound A-body system

D. Van Neck, S. Rombouts, S. Verdonck
Physical Review C
72 (5), 054318
2005
A1

Abstract 

We consider an exactly solvable Hamiltonian for bosons in one-dimension interacting through zero-range attractive forces, and construct a complete basis of its A-particle eigenstates. The structure of the single-particle spectral function in the removal domain is investigated, by taking the overlap of the A-particle ground state with the various excited states of the (A-1) system. In particular we study the contribution to the spectral function of the different break-up channels in the A-1 continuum, and compare the results to general statements available in the literature. It is shown that the asymptotic behavior in coordinate space does not agree with conventional assumptions. The relation to recent (e,e'p) experiments at large values of missing energy and momentum is pointed out.

The nuclear symmetry energy

A.E.L. Dieperink, D. Van Neck
Journal of Physics: Conference series
20(1),160-164
2005
A1

Abstract 

The role of isospin asymmetry in nuclei and neutron stars is discussed, with an emphasis on the density dependence of the nuclear symmetry energy. Results obtained with the self-consistent Green function method are presented and compared with various other theoretical predictions. Implications for the equation of state of a neutron star are discussed, and also possible constraints obtained from finite nuclei. | Source: International Symposium on Correlation Dynamics in Nuclei Book Series: JOURNAL OF PHYSICS CONFERENCE SERIES

Discrete approach to self-consistent GW calculations in an electron gas

Y. Dewulf, D. Van Neck, M. Waroquier
Physical Review B
71 (24),245122
2005
A1

Abstract 

Recent debate considering the importance of combining the GW approach to the electron gas with vertex corrections urges a calculation that can deal with both concepts in a self-consistent way. A major difficulty is the complicated energy dependence of the electron spectral function. We therefore propose an approximation for the Green’s function that may be very useful for tackling a more complete treatment of the electron gas problem. The key concept in this approach is the representation of the Green’s function by a limited number of carefully chosen poles. In this paper we present results for self-consistent GW calculation and find that they compare quite well to other self-consistent approaches. This legitimizes the use of this scheme as a practical tool for more involved calculations.

Why does the uncoupled hindered rotor model work well for the thermodynamics of n-alkanes?

V. Van Speybroeck, P. Vansteenkiste, D. Van Neck, M. Waroquier
Chemical Physics Letters
402 (4-6), 479 - 484
2005
A1

Abstract 

In this Letter, we unravel the origin of the good-behavior of the one-dimensional hindered rotor model to describe the partition function and derived thermodynamic properties of n-alkanes. The simplified uncoupled model predicts entropies of n-alkanes up to decane with a standard deviation less than 1% (P. Vansteenkiste, V. Van Speybroeck, G.B. Marin, M. Waroquier, J. Phys. Chem. A 107 (2003) 3139). Application of a fully coupled scheme for the internal rotations present in pentane and hexane gives a justification of the success of the uncoupled hindered rotor model based on microscopic grounds. The success of the separable rotor model is due to fortuitous cancellation of errors and cannot be generalized.

Nuclear symmetry energy and the neutron skin in neutron-rich nuclei

A.E.L. Dieperink, Y. Dewulf, D. Van Neck, M. Waroquier, V. Rodin
Physical Review C
68(6), 064307
2003
A1

Abstract 

The symmetry energy for nuclear matter and its relation to the neutron skin in finite nuclei is discussed. The symmetry energy as a function of density obtained in a self-consistent Green function approach is presented and compared to the results of other recent theoretical approaches. A partial explanation of the linear relation between the symmetry energy and the neutron skin is proposed. The potential of several experimental methods to extract the neutron skin is examined.

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