F.E. Ben Mohamed scite author profile

At present, we investigate the structure and the stability of NO(+)Arn (n ≤ 54) ionic clusters using analytical potential functions. The energy of these systems is described using additive potentials with VNO(+)Ar and VAr-Ar representing the pair potential interactions. To find the geometry of the lowest energy isomers of the NO(+)Arn clusters, we use the so-called basin hopping method of Wales et al. which combines a Monte-Carlo exploration and deformation method. The reliability of our model was checked by deriving the structures of the NO(+)Arn systems (n = 1, 2, 3 and 4) using ab initio Moller-Plesset perturbation theory up to second order (MP2) in connection with the aug-cc-pVTZ basis set. Magic numbers for sizes n = 8, 12, 18, 22, and 25 are found and they show a high relative stability. Our results reveal that a transition in the NO(+) ion coordination from 8 (square antiprism) to 12 (icosahedrons) occurs for n = 11. Examination of the stable structures of the ionic clusters demonstrates that the first solvation shell closes at n = 12. Furthermore, we found that the NO(+)Arn (n = 12-54) clusters are structurally very similar to the homogenous rare gas clusters with a polyicosahedral packing pattern. The distribution exhibits an additional magic number at n = 54, consistent with the completion of a second solvation sphere around NO(+). The effects of microsolvation of NO(+) cation in Ar clusters are also discussed. Generally, our results agree with the available experimental and theoretical findings on NO(+)Arn clusters and more generally on diatomics solvated in Ar clusters.

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Azo-methoxy-calix[4]arene complexes with metal cations for chemical sensor applications: Characterization, QTAIM analyses and dispersion-corrected DFT- computations

Gassoumi

Echabaane

Mohamed

et al. 2022

Spectrochimica Acta Part A: Molecular and Biomolecular Spectros

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Exploration of large amplitude motions in the Ca⁺Ar₂ complex

Mohamed

Amdouni³

et al. 2019

Molecular Physics

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Theoretical assessment of calix[4]arene-N-β-ketoimine (n=1–4) derivatives: Conformational studies, optoelectronic, and sensing of Cu2+cation

et al. 2021

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F.E. Ben Mohamed

In silico exploration of O-H…X2+ (X = Cu, Ag, Hg) interaction, targeted adsorption zone, charge density iso-surface, O-H proton analysis and topographic parameters theory for calix[6]arene and calix[8]arene as model

Microsolvation of NO+ in Arn clusters: A theoretical treatment

Azo-methoxy-calix[4]arene complexes with metal cations for chemical sensor applications: Characterization, QTAIM analyses and dispersion-corrected DFT- computations

Exploration of large amplitude motions in the Ca⁺Ar₂ complex

Theoretical assessment of calix[4]arene-N-β-ketoimine (n=1–4) derivatives: Conformational studies, optoelectronic, and sensing of Cu2+cation

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F.E. Ben Mohamed

In silico exploration of O-H…X2+ (X = Cu, Ag, Hg) interaction, targeted adsorption zone, charge density iso-surface, O-H proton analysis and topographic parameters theory for calix[6]arene and calix[8]arene as model

Microsolvation of NO+ in Arn clusters: A theoretical treatment

Azo-methoxy-calix[4]arene complexes with metal cations for chemical sensor applications: Characterization, QTAIM analyses and dispersion-corrected DFT- computations

Exploration of large amplitude motions in the Ca+Ar2 complex

Theoretical assessment of calix[4]arene-N-β-ketoimine (n=1–4) derivatives: Conformational studies, optoelectronic, and sensing of Cu2+cation

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Product

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Exploration of large amplitude motions in the Ca⁺Ar₂ complex