4.6 Article

Synthesize, characterization and topological properties of new hydrazone derivatives

Journal

JOURNAL OF MOLECULAR STRUCTURE
Volume 1251, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.molstruc.2021.132028

Keywords

Nucleophilic site; FTIR; Electrostatic potential surface

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New hydrazone derivatives, compound 1 and compound 2, have been synthesized by solid-state synthesis method and characterized using spectroscopic and quantum chemical calculations. The results show that compound 1 and compound 2 have different nucleophilic sites, and the molecular structures are predominantly stabilized by pi -> pi* interaction forces.
New hydrazone derivatives, [2-(Naphthalen-2-yloxy)-1-phenyl-ethylidene]-hydrazine (compound 1) and N-(2,4-Dinitro-phenyl)-N'-[2-(Naphthalen-2-yloxy)-1-phenyl-ethylidene]-hydrazine (compound 2) have been synthesized by solid-state synthesis method. These compounds have been characterized by spectroscopic (FTIR, (HNMR)-H-1, (CNMR)-C-13) techniques. Quantum chemical calculations have been carried out on these molecular structures. The results of the electrostatic potential (ESP) surface indicate that compound 1 has stronger nucleophilic site while compound 2 has stronger nucleophilic sites. Also, there is a flow of electrons from almost all the parts of the molecule towards the NO2 group attached at the para position in compound 2. The second order perturbation energy E(2) values show that the delocalization interactions involving the lone pair of electrons are much stronger than the other interactions but, the molecular geometries have been stabilized predominantly by the pi -> pi* interaction forces. The Laplacian of electron density. del(2) rho(BCP) profile suggest that co-valent character of the C-H bonds of naphthyl and phenyl rings of compound 2 have been enhanced by the substitution of 2,4-Dinitro Phenyl hydrazine. The. del(2) rho(BCP) values qualitatively have good correlation with the decrement/increment of electron density around some of the carbon nuclei as signalled by the NMR chemical shift positions. (C) 2021 Elsevier B.V. All rights reserved.

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