Affiliations: [a]
Institute of Applied Mathematics and Physics, Shanghai DianJi University, Shanghai, People’s Republic of China | [b]
Technology Transfer Center, Chinese Academy of Sciences, Dongguan, People’s Republic of China
Correspondence:
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Corresponding author: Run-Ning Zhao, Institute of Applied Mathematics and Physics, Shanghai DianJi University, Shanghai 201306, People’s Republic of China; E-mail: [email protected] and Zi-Chen Lu, Technology Transfer Center, Chinese Academy of Sciences, Dongguan 523808, People’s Republic of China.
Abstract: Clusters of the WNn (n = 1–9) forms are investigated theoretically using density functional theory methods. Geometry optimizations are undertaken under the constraint of well-defined point-group symmetries at the (U)B3LYP level employing a pseudopotential method in conjunction with double-zeta basis sets for W atom and 6–31G(d) basis sets for N atoms. In this article, different molecular properties such as total energies, relative stabilities as well as chemical bonding and equilibrium geometries of WNn (n = 1–9) clusters are systematically calculated and discussed. Theoretical results show that the lowest-energy WNn (n = 1–9) isomers prefer to interact with N2 units to N3 and N units, moreover, some circle-like low-lying stable WNn structures are considered, which turn out to be less stable than isomers with N2 units as the building blocks, furthermore, W atom is in favorable of chemisorption nitrogen rather than dissociative nitrogen, which is in good agreement with experimental observation. Comparisons theoretical results on geometry and stretching frequency with available experimental and theoretical data are made, a good agreement is obtained. In addition, natural population analyses are calculated in order to elucidate the charge distributions in the clusters.
