A mathematical and computational review of Hartree–Fock SCF methods in quantum chemistry

Echenique, Pablo; Alonso, José L.

doi:10.1080/00268970701757875

Cited by 101 publications

(91 citation statements)

References 162 publications

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“…The simplest ab initio method is the application of the Hartree-Fock (HF) theory [116]. In the HF method, a system is reduced to a series of one-electron wave functions where each electron moves in an average field due to the other electrons.…”

Section: Quantum Mechanical Methodsmentioning

confidence: 99%

Assessment of theoretical methods for the study of hydrogen abstraction kinetics of global warming gas species during their degradation and byproduct formation (IUPAC Technical Report)

Ramasami

Abdallah

Archibong

et al. 2013

Pure and Applied Chemistry

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Global climate change is a major concern as it leads to an increase in the average temperature of the earth's atmosphere. The existence and persistence of some gaseous species in the atmosphere contribute to global warming. Experimental techniques are used to study the kinetics and degradation of global warming gases. However, quantum mechanical methods are also useful for the kinetic and radiative forcing study of global warming species and can precede experimental investigations. Research has also been targeted to develop more adapted procedures using ab initio and density functional theory (DFT) methods. This report provides a global perspective, in simplified manner, of the theoretical studies of the degradation of gas species in the atmosphere with an emphasis on the hydrogen abstraction kinetics of global warming gas species during their degradation and byproduct formation. En route, the results obtained from these studies are analysed and compared with experimental data where available. Our analyses indicate that the theoretical predictions are in agreement with experimental findings but the predicted parameters are dependent on the method being used. Theoretical methods are used to predict the thermodynamic parameters of reactions, and, with relevance to this report, the global warming potential (GWP) index can also be calculated. This report can be useful for future investigations involving global warming gaseous species while providing suggestions on how computations can fill in data gaps when experimental data are unavailable.

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Section: Quantum Mechanical Methodsmentioning

confidence: 99%

Assessment of theoretical methods for the study of hydrogen abstraction kinetics of global warming gas species during their degradation and byproduct formation (IUPAC Technical Report)

Ramasami

Abdallah

Archibong

et al. 2013

Pure and Applied Chemistry

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“…The Hartree-Fock (HF) method [9], also known as the self-consistent field (SCF) method, is an approximation method that is used to determine the wavefunction and the energy of a quantum system. In the HF method, there is an assumption that the wavefunction can be approximated using a single Slater determinant (a representation of the wavefunction).…”

Section: The Schrödinger Equationmentioning

confidence: 99%

Developing a New Storage Format and a Warp-Based SpMV Kernel for Configuration Interaction Sparse Matrices on the GPU

Mahmoud¹,

Hoffmann²,

Reza³

2018

Computation

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Sparse matrix-vector multiplication (SpMV) can be used to solve diverse-scaled linear systems and eigenvalue problems that exist in numerous, and varying scientific applications. One of the scientific applications that SpMV is involved in is known as Configuration Interaction (CI). CI is a linear method for solving the nonrelativistic Schrödinger equation for quantum chemical multi-electron systems, and it can deal with the ground state as well as multiple excited states. In this paper, we have developed a hybrid approach in order to deal with CI sparse matrices. The proposed model includes a newly-developed hybrid format for storing CI sparse matrices on the Graphics Processing Unit (GPU). In addition to the new developed format, the proposed model includes the SpMV kernel for multiplying the CI matrix (proposed format) by a vector using the C language and the Compute Unified Device Architecture (CUDA) platform. The proposed SpMV kernel is a vector kernel that uses the warp approach. We have gauged the newly developed model in terms of two primary factors, memory usage and performance. Our proposed kernel was compared to the cuSPARSE library and the CSR5 (Compressed Sparse Row 5) format and already outperformed both.

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“…(47) of such an energy function, we see that the quantities, say, l 0 α and θ 0 α , appearing in the harmonic energy terms associated to bond lengths and bond angles, are readily available to be elected as the candidate constant numbers to which equate this coordinates should we want to consider them as 'stiff' and constrain them; even if they are not, as mentioned, the actual minimum-energy values of the bond lengths and bond angles in any given conformation of the molecule. If, instead of a force field, we consider a less explicit energy function, such as the one produced by the ground-state Born-Oppenheimer approximation for the electrons in quantum chemistry [23,136], then no candidate number appears before our eyes as the constants to be used in the constrained model, and the flexible way of proceeding is even more natural.…”

Section: Flexible Vs Hard Constraintsmentioning

confidence: 99%

“…The fact that all these issues are intricately coupled is easily seen if we consider examples such as the comparison between ab initio MD based on the ground-state Born-Oppenheimer approximation [1,12,13,14,15] and MD simulations using as energy functions the ones known as classical force fields [16,17,18,19,20,21]. On the one hand, it is clear that the accuracy of the two physical models is not the same; on the other hand, the size of the systems that can be practically tackled is also different, since quantum chemical methods present a cost that scales typically faster with the number of atoms than that of force fields [22,23]. Another example of this interplay between accuracy and cost is the use of coarse-grained descriptions, which, by selecting as interaction centers larger entities than individual atoms, and thus changing the physical model, allow to reach larger systems and longer time-scales than atomistic simulations using either force fields or ab initio methods [24,25,26,27,28].…”

Section: Introductionmentioning

confidence: 99%

The canonical equilibrium of constrained molecular models

Echenique

Cavasotto

García-Risueño

2011

Eur. Phys. J. Spec. Top.

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Abstract. In order to increase the efficiency of the computer simulation of biological molecules, it is very common to impose holonomic constraints on the fastest degrees of freedom; normally bond lengths, but also possibly bond angles. Since the maximum time step required for the stability of the dynamics is proportional to the shortest period associated with the motions of the system, constraining the fastest vibrations allows to increase it and, assuming that the added numerical cost is not too high, also increase the overall efficiency of the simulation. However, as any other element that affects the physical model, the imposition of constraints must be assessed from the point of view of accuracy: both the dynamics and the equilibrium statistical mechanics are model-dependent, and they will be changed if constraints are used. In this review, we investigate the accuracy of constrained models at the level of the equilibrium statistical mechanics distributions produced by the different dynamics. We carefully derive the canonical equilibrium distributions of both the constrained and unconstrained dynamics, comparing the two of them by means of a "stiff" approximation to the latter. We do so both in the case of flexible and hard constraints, i.e., when the value of the constrained coordinates depends on the conformation and when it is a constant number. We obtain the different correcting terms associated with the kinetic energy mass-metric tensor determinants, but also with the details of the potential energy in the vicinity of the constrained subspace (encoded in its first and second derivatives). This allows us to directly compare, at the conformational level, how the imposition of constraints changes the thermal equilibrium of molecular systems with respect to the unconstrained case. We also provide an extensive review of the relevant literature, and we show that all models previously reported can be considered special cases of the most general treatments presented in this work. Finally, we numerically analyze a simple methanol molecule in order to illustrate the theoretical concepts in a practical case.

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A mathematical and computational review of Hartree–Fock SCF methods in quantum chemistry

Cited by 101 publications

References 162 publications

Assessment of theoretical methods for the study of hydrogen abstraction kinetics of global warming gas species during their degradation and byproduct formation (IUPAC Technical Report)

Assessment of theoretical methods for the study of hydrogen abstraction kinetics of global warming gas species during their degradation and byproduct formation (IUPAC Technical Report)

Developing a New Storage Format and a Warp-Based SpMV Kernel for Configuration Interaction Sparse Matrices on the GPU

The canonical equilibrium of constrained molecular models

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