Degree-Based Entropy for a Non-Kekulean Benzenoid Graph

Tessellations of kekulenes and cycloarenes have a lot of potential as nanomolecular belts for trapping and transporting heavy metal ions and chloride ions because they have the best electronic properties and pore sizes. The aromaticity, superaromaticity, chirality, and novel electrical and magnetic...

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Bibliographic Details
Published inJournal of mathematics (Hidawi) Vol. 2022; no. 1
Main Authors Ashraful Alam, Md, Ghani, Muhammad Usman, Kamran, Muhammad, Shazib Hameed, Muhammad, Hussain Khan, Riaz, Baig, A. Q.
Format Journal Article
LanguageEnglish
Published Cairo Hindawi 2022
Hindawi Limited
Wiley
Subjects
Aromaticity
Belt conveyors
Biological activity
Biological properties
Biology
Chemistry
Chirality
Chloride ions
Connectivity
Crystal structure
Electron energy
Entropy
Geometry
Heavy metals
Information theory
Iterative methods
Magnetic properties
Mathematics
Physical properties
Pi-electrons
Topology
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Summary:Tessellations of kekulenes and cycloarenes have a lot of potential as nanomolecular belts for trapping and transporting heavy metal ions and chloride ions because they have the best electronic properties and pore sizes. The aromaticity, superaromaticity, chirality, and novel electrical and magnetic properties of a class of cycloarenes known as kekulenes have been the subject of several experimental and theoretical studies. Through topological computations of superaromatic structures with pores, we investigate the entropies and topological characterization of different tessellations of kekulenes. Using topological indices, the biological activity of the underlying structure is linked to its physical properties in (QSPR/QSAR) research. There is a wide range of topological indices accessible, including degree-based indices, which are used in this work. With the total π-electron energy, these indices have a lot of iteration. In addition, we use graph entropies to determine the structural information of a non-Kekulean benzenoid graph. In this article, we study the crystal structure of non-Kekulean benzenoid graph Kn and then calculate some entropies by using the degree-based topological indices. We also investigate the relationship between degree-based topological indices and degree-based entropies. This relationship is very helpful for chemist to study the physicochemical characterization of non-Kekulean benzenoid chemical. These numerical values correlate with structural facts and chemical reactivity, biological activities, and physical properties.
ISSN:2314-4629
2314-4785
DOI:10.1155/2022/2288207