Abstract
A topological index is a quantitative measure of molecular structure and connection. It also estimates the toxicological, structural, biological, and physicochemical characteristics of a chemical molecule. The use of nano-structured graphs in the study of chemistry is very extensive. Melem, one of the most significant tri−s−triazine compounds, is a nucleophilic reagent that may be employed in reactions with derivatives of phthalic acid. Materials with borophene nanostructures are also exploited in cross-disciplinary research. In comparison to carbon hexagonal nanotubes, boron triangular nanotubes are thought to be a superior conductor. The goal of computing the multiplicative Zagreb connection indices for Chemical graphs is to understand the complexity, connectedness, and chemical activity of molecules. Information is useful in a number of applications, including drug design, chemical synthesis, and property prediction. In this paper, we compute the first, second, third, fourth, and fifth multiplicative Zagreb connection indices (ZCIs) of the melem chain MC(s), the borophene chain B36(s), and the boron triangular sheet BTS(m,s).
Graphical Abstract
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