A Chemically Meaningful Measure of Electron Localization

Rahm, Martin

doi:10.1021/acs.jctc.5b00396

Cited by 15 publications

(19 citation statements)

References 77 publications

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“…The electron density in the tail of Group 1 atoms is special in this sense, because it arises from only one s‐electron, which is isolated or separate relative to same spin‐counterparts. Same‐spin loneliness is one measure of electron localization, and can be viewed as the primary cause behind steric strain in and between molecules. This qualitatively explains how a given outer electron density in Group 1 atoms can generate a larger repulsion toward the electrons of neighboring atom, compared to the same (mixed‐spin) density of other atoms.…”

Section: Comparison With Van Der Waals Radii Based On Structuresmentioning

confidence: 96%

“…There are variations to be avoided (see the Li curve) until the density settles down to its expected exponential falloff. The Boyd density cutoff has been used as a practical outer boundary for quantum chemical topology domains . Other limiting values have been proposed, and variable isodensity surfaces have been used for the construction of solvation spheres in implicit solvation models …”

Section: A Density Metric For Atomic Radiimentioning

confidence: 99%

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Atomic and Ionic Radii of Elements 1–96

Rahm

Hoffmann

Ashcroft

2016

Chemistry A European J

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268

219

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Atomic and cationic radii have been calculated for the first 96 elements, together with selected anionic radii. The metric adopted is the average distance from the nucleus where the electron density falls to 0.001 electrons per bohr(3) , following earlier work by Boyd. Our radii are derived using relativistic all-electron density functional theory calculations, close to the basis set limit. They offer a systematic quantitative measure of the sizes of non-interacting atoms, commonly invoked in the rationalization of chemical bonding, structure, and different properties. Remarkably, the atomic radii as defined in this way correlate well with van der Waals radii derived from crystal structures. A rationalization for trends and exceptions in those correlations is provided.

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Section: Comparison With Van Der Waals Radii Based On Structuresmentioning

confidence: 96%

Section: A Density Metric For Atomic Radiimentioning

confidence: 99%

Atomic and Ionic Radii of Elements 1–96

Rahm

Hoffmann

Ashcroft

2016

Chemistry A European J

Self Cite

268

219

View full text Add to dashboard Cite

show abstract

“…The intuitive concept of electron localization and delocalization is widely used in chemistry to qualitatively interpret various properties of molecules, molecular systems, and solids . It is commonly associated with specific distribution of electrons which are accumulated in the certain spatial regions or are spread out over some atomic groups.…”

Section: Introductionmentioning

confidence: 99%

Spatially resolved characterization of electron localization and delocalization in molecules: Extending the Kohn‐Resta approach

Astakhov

Tsirelson

2018

Int J of Quantum Chemistry

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In this work, the electron organization of many‐electron systems is considered in a context of the linear response theory extending the Kohn‐Resta view on electron localization phenomenon. The variances of the local electronic position and momentum operators are linked via the fluctuation‐dissipation theorem to the optical conductivity tensor, that is, to observable spectroscopic properties. It is demonstrated that the electron position variance density quantifies a degree of electron delocalization in each point of position space and distinguishes between metallic and insulating character of electronic states. The momentum variance density estimates a degree of electron localization and is immediately related to electronic kinetic energy density in the Ghosh‐Berkowitz‐Parr form giving a physical interpretation to the later. We show that electron localization and delocalization phenomena in atoms and molecules can be probed by external electric field. This approach provides new electronic descriptors distinguishing and quantifying chemical bonds of different types.

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“…The physical foundations of the VSEPR model have been extensively researched in the framework of the electron‐pair density and, moreover, numerous studies based on the gradient field of density functions have supported its original principles . Indeed, these works brought knowledge on the role of the electron‐pair domains, defined as regions of space in which the probability of finding two opposite‐spin electrons is high . Among the density functions, the so‐called electron localization function (ELF) helped for the good application of the VSEPR model, in particular to hypervalent molecules .…”

Section: Introductionmentioning

confidence: 99%

The bonding picture in hypervalent XF₃ (X = Cl, Br, I, At) fluorides revisited with quantum chemical topology

et al. 2017

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Hypervalent XF (X = Cl, Br, I, At) fluorides exhibit T-shaped C equilibrium structures with the heavier of them, AtF , also revealing an almost isoenergetic planar D structure. Factors explaining this behavior based on simple "chemical intuition" are currently missing. In this work, we combine non-relativistic (ClF ), scalar-relativistic and two-component (X = Br - At) density functional theory calculations, and bonding analyses based on the electron localization function and the quantum theory of atoms in molecules. Typical signatures of charge-shift bonding have been identified at the bent T-shaped structures of ClF and BrF , while the bonds of the other structures exhibit a dominant ionic character. With the aim of explaining the D structure of AtF , we extend the multipole expansion analysis to the framework of two-component single-reference calculations. This methodological advance enables us to rationalize the relative stability of the T-shaped C and the planar D structures: the Coulomb repulsions between the two lone-pairs of the central atom and between each lone-pair and each fluorine ligand are found significantly larger at the D structures than at the C ones for X = Cl - I, but not with X = At. This comes with the increasing stabilization, along the XF series, of the planar D structure with respect to the global T-shaped C minima. Hence, we show that the careful use of principles that are at the heart of the valence shell electron pair repulsion model provides reasonable justifications for stable planar D structures in AX E systems. © 2017 Wiley Periodicals, Inc.

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A Chemically Meaningful Measure of Electron Localization

Cited by 15 publications

References 77 publications

Atomic and Ionic Radii of Elements 1–96

Atomic and Ionic Radii of Elements 1–96

Spatially resolved characterization of electron localization and delocalization in molecules: Extending the Kohn‐Resta approach

The bonding picture in hypervalent XF₃ (X = Cl, Br, I, At) fluorides revisited with quantum chemical topology

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A Chemically Meaningful Measure of Electron Localization

Cited by 15 publications

References 77 publications

Atomic and Ionic Radii of Elements 1–96

Atomic and Ionic Radii of Elements 1–96

Spatially resolved characterization of electron localization and delocalization in molecules: Extending the Kohn‐Resta approach

The bonding picture in hypervalent XF3 (X = Cl, Br, I, At) fluorides revisited with quantum chemical topology

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The bonding picture in hypervalent XF₃ (X = Cl, Br, I, At) fluorides revisited with quantum chemical topology