The role of tagging atoms on the thermal stability and vibrational behavior of Nb9 clusters
Article
-
- Overview
-
- Research
-
- Identity
-
- Additional Document Info
-
- View All
-
Overview
abstract
-
Extensive comparative study of density functional theory calculations dedicated to analyzed the influence of the so-called tagging atoms on the thermal stability and vibrational behavior of small Nb9—Arn (n = 1–4) clusters are presented. We consider two-hybrid functional (HSEH1PBE and CAM-B3LYP) models to obtain minimum energy structures and, the relative concentrations of several Ar complexes configurations when varying the temperature of the system are determined by constructing partition functions and enthalpies. Under these considerations, it was found that the coexistence of two different isomers of the Nb9 clusters in a sample is highly probable. Additionally, some interesting points can be highlighted, for instance, i) the different hybrid exchange-correlation functionals modify the proportions of mole fractions in all cases, ii) the weighted average of the IR spectra proposed by the mole fractions have better agreement with the experimental data, iii) tagging atoms can induce significant variations in the infrared spectra, such variations consist mainly of noticeable changes in the relative intensity of the active infrared frequencies. In conclusion, even if the percentage of isomers shown in the mole fractions changes as a function of the hybrid exchange-correlation functional, the influence of tagging atoms makes some changes in the calculation of the partition function and in the simulated IR spectra. For this reason, it is suggested to include tagging atoms in theoretical calculations to have a better understanding of the experimental data. © 2022
publication date
funding provided via
published in
Research
keywords
-
Density functional theory; Isomers; Thermodynamic stability; Comparatives studies; Density-functional theory calculations; Exchange-correlation functionals; Hybrid exchange; Hybrid functional; IR spectrum; Molefraction; Partition functions; Stability behavior; Vibrational behavior; Atoms
Identity
Digital Object Identifier (DOI)
PubMed ID
Additional Document Info
start page
end page
volume
issue