Weighted entropies of Tuc5c8[P;Q] nanotube with the degree based topological indices as weights

Afzal, Farkhanda; Afzal, Faiza; Afzal, Deeba; Farahani, Mohammad Reza; Cancan, Murat; Ediz, Suleyman

doi:10.22034/ecc.2021.120281

Document Type : Original Research Article

Authors

¹ MCS, National University of Sciences and Technology, Islamabad, Pakistan

² Department of Mathematics and Statistics, The University of Lahore, Lahore, 54000, Pakistan

³ Department of Applied Mathematics, Iran University of Science and Technology, Tehran, Iran

⁴ Faculty of Education, Van Yuzuncu Yıl University, Zeve Campus, Tuşba, 65080, Van, Turkey

https://doi.org/10.22034/ecc.2021.120281

Abstract

The entropy of a graph is a function depending both on the graph itself and on a probability distribution on its vertex set. This graph function originated in the problem of source coding in information theory and was introduced by J. Krner in 1973. Although the notion of graph entropy has its roots in information theory, it was proved to be closely related to some classical and frequently studied graph theoretic concepts. In this article, we captured the symmetry present in the structure of molecular graph of nanotube. We computed entropies of TUC₅C₈[p;q] nanotube taking some degree-based topological indices as edge weights.

Graphical Abstract

Keywords

Main Subjects

Computational Chemistry

References

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Eurasian Chemical Communications

Weighted entropies of Tuc5c8[P;Q] nanotube with the degree based topological indices as weights

References

References

Volume 3, Issue 1
January 2021
Pages 14-18

Weighted entropies of Tuc5c8[P;Q] nanotube with the degree based topological indices as weights

References

References

Volume 3, Issue 1January 2021Pages 14-18

Volume 3, Issue 1
January 2021
Pages 14-18