Bonding features in Appel's salt from the orbital-free quantum crystallographic perspective

Барташевич, Е. В.; Сташ, А. И.; Yushina, I. D.; Minyaev, Mikhail E.; Bol’shakov, Oleg; Ракитин, Олег А.; Tsirelson, Vladimir G.

doi:10.1107/s2052520621005928

Cited by 12 publications

(24 citation statements)

References 74 publications

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“…reaching a minimal value in the charge-shift S-S bond. This conclusion, in general, agrees with bond-order indices estimated from theoretical electron density: they decrease in a similar way (Bartashevich et al, 2021). The smaller the electronic potential energy at the b.c.p.s, the weaker the covalent bond strength.…”

Section: Examplessupporting

confidence: 88%

“…Many other examples may be additionally found in very recent work by Tsirelson & Stash (2020, Bartashevich et al (2021) and Shteingolts et al (2021).…”

Section: Examplesmentioning

confidence: 78%

“…This approach arose recently from studies of electron density in crystals (Tsirelson & Ozerov, 1996;Gatti & Macchi, 2012;Stalke, 2012) within the framework of the orbital-free density functional theory (Wesolowski & Wang, 2013), information theory (Nalewajski, 2006), and an extension of Bader's quantum theory (Bader, 1990) of atoms in molecules and crystals Tsirelson, 2007). Early work has demonstrated the effectiveness of this approach (Shteingolts et al, 2021;Stash et al, 2021;Bartashevich et al, 2021). We report here the release of a software package consisting of the WinXPRO (version 3.4.51), 3DPlot (version 2.5.26) and TrajPlot (version 1.4.0.2) programs.…”

Section: Introductionmentioning

confidence: 99%

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WinXPRO, 3DPlot and TrajPlot computer software: new options for orbital-free quantum crystallography studies

Сташ¹,

Tsirelson²

2022

J Appl Cryst

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Section: Examplessupporting

confidence: 88%

“…Many other examples may be additionally found in very recent work by Tsirelson & Stash (2020, Bartashevich et al (2021) and Shteingolts et al (2021).…”

Section: Examplesmentioning

confidence: 78%

Section: Introductionmentioning

confidence: 99%

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WinXPRO, 3DPlot and TrajPlot computer software: new options for orbital-free quantum crystallography studies

Сташ¹,

Tsirelson²

2022

J Appl Cryst

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“…The topology of 𝜑 𝑒𝑠 (𝒓) 54,57,58 in combination with 𝜌-basins is widely employed for describing electrostatic contribution for various interactions in associates and crystals. 14,15,66,17,[59][60][61][62][63][64][65] Further, the gap between 𝜑 𝑒𝑠 -and 𝜌-basins is attributed to phenomena of interatomic charge (electron) transfer and can be used to estimate it. 15 However, although 𝜑 𝑘 -basins (pseudoatoms) and corresponding kinetic force field have a robust physical definition, it is not clear for now how it can be exploited to retrieve chemical information.…”

mentioning

confidence: 99%

“…15 The examination of electronic potentials can serve to enhance or even substitute the use of existing chemical descriptors: for example, the analysis of 𝜑 𝑒𝑚 (𝒓) can be considered as a viable or even preferable alternative to 𝜑 𝑒𝑠 (𝒓). 15,66 Nevertheless, it is worth noting the widespread use of 𝜑 𝑒𝑠 (𝒓) for the explanation and prediction of chemical behavior. [68][69][70][71][72][73][74][75][76] The Pauli potential 𝜑 𝑃 (𝒓)…”

mentioning

confidence: 99%

Real-Space Interpretation of Interatomic Charge Transfer and Electron Exchange Effects by Combining Static and Kinetic Potentials and Associated Vector Fields

Shteingolts

Stash

Tsirelson

et al. 2022

Preprint

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Intricate behavior of one-electron potentials from the Euler equation for electron density and corresponding gradient force fields in crystals was studied. Bosonic and fermionic quantum potentials were utilized in bonding analysis as descriptors of the localization of electrons and electron pairs. Channels of locally enhanced kinetic potential and the corresponding saddle Lagrange points were found between chemically bonded atoms linked by the bond paths. Superposition of electrostatic φ_es (r) and kinetic φ_k (r) potentials and electron density ρ(r) allowed partitioning any molecules and crystals into atomic ρ- and potential-based φ-basins; the φ_k-basins explicitly account for electron exchange effect, which is missed for φ_es-ones. Phenomena of interatomic charge transfer and related electron exchange were explained in terms of space gaps between ρ- and φ-zero-flux surfaces. The gap between φ_es- and ρ-basins represents the charge transfer, while the gap between φ_k- and ρ-basins is proposed to be a real-space manifestation of sharing the transferred electrons. The position of φ_k-boundary between φ_es- and ρ-ones within an electron occupier atom determines the extent of electron sharing. The stronger an H‧‧‧O hydrogen bond is, the deeper hydrogen atom’s φ_k-basin penetrates oxygen atom’s ρ-basin. For covalent bonds, a φ_k-boundary closely approaches a φ_es-one indicating almost complete sharing the transferred electrons, while for ionic bonds, the same region corresponds to electron pairing within the ρ-basin of an electron occupier atom.

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Real‐Space Interpretation of Interatomic Charge Transfer and Electron Exchange Effects by Combining Static and Kinetic Potentials and Associated Vector Fields**

Shteingolts

Сташ

Tsirelson

et al. 2022

Chemistry A European J

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Intricate behaviour of one‐electron potentials from the Euler equation for electron density and corresponding gradient force fields in crystals was studied. Channels of locally enhanced kinetic potential and corresponding saddle Lagrange points were found between chemically bonded atoms. Superposition of electrostatic ϕesboldr and kinetic ϕkboldr potentials and electron density ρboldr allowed partitioning any molecules and crystals into atomic ρ ‐ and potential‐based ϕ ‐basins; ϕk ‐basins explicitly account for the electron exchange effect, which is missed for ϕes ‐ones. Phenomena of interatomic charge transfer and related electron exchange were explained in terms of space gaps between zero‐flux surfaces of ρ ‐ and ϕ ‐basins. The gap between ϕes ‐ and ρ ‐basins represents the charge transfer, while the gap between ϕk ‐ and ρ ‐basins is a real‐space manifestation of sharing the transferred electrons caused by the static exchange and kinetic effects as a response against the electron transfer. The regularity describing relative positions of ρ ‐, ϕes ‐, and ϕk ‐ basin boundaries between interacting atoms was proposed. The position of ϕk ‐boundary between ϕes ‐ and ρ ‐ones within an electron occupier atom determines the extent of transferred electron sharing. The stronger an H⋅⋅⋅O hydrogen bond is, the deeper hydrogen atom's ϕk ‐basin penetrates oxygen atom's ρ ‐basin, while for covalent bonds a ϕk ‐boundary closely approaches a ϕes ‐one indicating almost complete sharing of the transferred electrons. In the case of ionic bonds, the same region corresponds to electron pairing within the ρ ‐basin of an electron occupier atom.

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Bonding features in Appel's salt from the orbital-free quantum crystallographic perspective

Cited by 12 publications

References 74 publications

WinXPRO, 3DPlot and TrajPlot computer software: new options for orbital-free quantum crystallography studies

WinXPRO, 3DPlot and TrajPlot computer software: new options for orbital-free quantum crystallography studies

Real-Space Interpretation of Interatomic Charge Transfer and Electron Exchange Effects by Combining Static and Kinetic Potentials and Associated Vector Fields

Real‐Space Interpretation of Interatomic Charge Transfer and Electron Exchange Effects by Combining Static and Kinetic Potentials and Associated Vector Fields**

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