Charge‐Shift Bonding—A Class of Electron‐Pair Bonds That Emerges from Valence Bond Theory and Is Supported by the Electron Localization Function Approach

Shaik, Sason; Silvi, Bernard; Lauvergnat, David; Hiberty, Philippe C.

doi:10.1002/chem.200500265

Cited by 248 publications

(343 citation statements)

References 153 publications

(125 reference statements)

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“…3. Basins 11+19 and 10+15 (similar basin splitting is observed for F2 [2]) each total 0.91e; again less than a pair (Wiberg index 0.63). So the three Cl-F bonds are 4.…”

supporting

confidence: 57%

VSEPR Theory: A closer look at chlorine trifluoride, ClF3.

Rzepa¹

2015

The Winnower

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“…3. Basins 11+19 and 10+15 (similar basin splitting is observed for F2 [2]) each total 0.91e; again less than a pair (Wiberg index 0.63). So the three Cl-F bonds are 4.…”

supporting

confidence: 57%

VSEPR Theory: A closer look at chlorine trifluoride, ClF3.

Rzepa¹

2015

The Winnower

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“…These features are common to the VBSCF, BOVB and VBCI methods (see below), and their use has resulted in some new qualitative concepts. [106][107][108] Moreover, owing to the use of strictly localized active orbitals, these methods are suitable for calculating clearly defined diabatic states that are required to retain the physical content of a given asymptotic state, at any point of a reaction coordinate, without collapsing to the ground state by virtue of uncontrolled orbital optimization. 25,109,110 The Valence Bond Self Consistent Field Method…”

Section: Pure Vb Methods That Use Localized Orbitalsmentioning

confidence: 99%

“…One such paradigm is called ''charge-shift bonding'' and concerns two-electron bonds which are neither covalent nor ionic but with bonding energy that is dominated by the covalent-ionic resonance interaction; for example FÀ ÀF and OÀ ÀO are charge-shift bonds. 107,154 Another paradigm is the ''ferromagnetic-bonding'' that occurs in high-spin clusters, e.g., n+1 Li n , n+1 Cu n , etc. that are devoid of an electron pairs but have significant bond energy that can reach as much as 19 kcal/mol per atom.…”

Section: Concluding Remarks and Prospectivementioning

confidence: 99%

A survey of recent developments in ab initio valence bond theory

Hiberty

Shaik

2006

J Comput Chem

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Starting from the 1980s and onwards, Valence Bond theory has been enjoying renaissance that is characterized by the development of a growing number of ab initio methods, and by many applications to chemical reactivity and to the central paradigms of chemistry. Owing the increase of computational power of modern computers and to significant advances in the methodology, valence bond theory begins to offer a sound and attractive alternative to Molecular Orbital theory. This review aims at summarizing the most important developments of ab initio valence bond methods during the last two or three decades, and is primarily devoted to a description of what the various methods can actually achieve within their specific scopes and limitations. Key available softwares are surveyed.

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“…However, it has always been our experience that some ab initio VB methods, providing static and dynamic correlations [9][10][11][36][37][38], are able to give quantitative results as well as physical insight by means of very compact wave functions, with a very small number of chemically lucid VB structures. Examples involve dissociation reactions of twoelectron bonds [9,39] and three-electron bonds [40], reaction barriers [41,42], transition energies [43], and so on [7]. Thus, in view of the difficulties encountered by many researchers and the elaborate strategies that had to be devised to describe the V state of ethylene with MO-CI methods, we decided to address the problem by the use of ab initio VB methods, with the aim of getting accurate values of N ?…”

Section: Introductionmentioning

confidence: 99%

The V state of ethylene: valence bond theory takes up the challenge

Zhang

Braı̈da

et al. 2014

Theor Chem Acc

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HAL is a multi-disciplinary open access archive for the deposit and dissemination of scientific research documents, whether they are published or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. Further improvement to 7.96/7.93 eV is achieved at the variational and diffusion Monte Carlo (MC) levels, respectively, VMC/DMC, using a Jastrow factor coupled with the same compact VB wave function. Furthermore, the measure of the spatial extension of the V state wave function, 19.14 a 0 2 , is in the range of accepted values obtained by large-scale state-of-the-art molecular orbitalbased methods. The r response to the fluctuations of the p electrons in the V state, known to be a crucial feature of the V state, is taken into account using the breathing orbital valence bond method, which allows the VB structures to have different sets of orbitals. Further valence bond calculations in a larger space of configurations, involving explicit participation of the r response, with 9 VB structures for the N state and 14 for the V state, confirm the results of the minimal structure set, yielding an N ? V transition energy of 7.97 eV and a spatial extension of 19.16 a 0 2 for the V state. Both types of valence bond calculations show that the V state of ethylene is not fully ionic as usually assumed, but involving also a symmetryadapted combination of VB structures each with asymmetric covalent p bonds. The latter VB structures have cumulated weights of 18-26 % and stabilize the V state by about 0.9 eV. It is further shown that these latter VB structures, rather than the commonly considered zwitterionic ones, are the ones responsible for the spatial extension of the V state, known to be ca. 50 % larger than the V state.Keywords Valence bond Á Quantum Monte Carlo Á V state of ethylene Á Breathing orbitals 1 Introduction

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Charge‐Shift Bonding—A Class of Electron‐Pair Bonds That Emerges from Valence Bond Theory and Is Supported by the Electron Localization Function Approach

Cited by 248 publications

References 153 publications

VSEPR Theory: A closer look at chlorine trifluoride, ClF3.

VSEPR Theory: A closer look at chlorine trifluoride, ClF3.

A survey of recent developments in ab initio valence bond theory

The V state of ethylene: valence bond theory takes up the challenge

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