Molecular Descriptors on Line Graphs of Cactus Chains and Rooted Products Graphs

The application of graph theory in the study of molecular physical and chemical properties involves theoretical mathematical chemistry. Atoms, represented by vertices, and edges, represented by bonds between them, are detailed in simple graphs called chemical graphs. The mathematical derivation of the numerical value of a graph is called the molecular descriptor of the graph. Any connected graph wherein no edge is contained in exclusive of a single cycle is called a cactus graph. In the research in this article, expressions for various molecular descriptors of line graph of the graph obtained by the rooted product of the cycle and path graphs are constructed. This article obtained the calculation of molecular descriptors for line graphs of chain ortho cactus and chain para cactus graphs. To predict the biological activity of a compound, the generalized Zagreb index, the ﬁ rst Zagreb index M 1 ð G Þ , the second Zagreb index M 2 ð G Þ , the F-index, the general Randic index, the symmetric division, the atom bond connectivity (ABC), and the geometric arithmetic (GA) descriptors are created.


Introduction
The branch of mathematical chemistry that relates to other sciences, engineering, and especially chemistry is called chemical graph theory. An ordered pair of a couple of sets ðVðGÞ, EðGÞÞ, where ðVðGÞÞ is called the set of vertices and EðGÞ the set of edges, constitutes the graph G. The number of vertices of a graph apart from the vertex v that are incident on v is a natural number that is termed as the degree of the veterx v denoted by dv or d G ðvÞ. A graph obtained by some other graph wherein the vertices of the resulting graph are edges of the original graph G is called a line graph LðGÞ of the original graph G. The number mathematically determined by the graph is called the topological index of the graph, and this number remains constant for isomorphic graphs. Lately, many researchers have discovered quite a few number of molecular descriptors that cover a wide range of chemistry applications and cover biochemistry, medicine, and other fields to theoretically understand the physicochemical properties of chemical compounds. The blocks of a chain cactus graph can either be edges or cycles. If all the blocks of a chain cactus graph are triangular, then it will be termed as a triangular cactus graph. Chain square cactus graphs are those in which the triangles in the chain have been replaced with cycles of length 4. The articulation points in case of ortho chain square cactus are contiguous as against para chain square cactus wherein the articulation points are not contiguous. Sadeghieh et al. [1] performed a derivation of Hosoya polynomial of quite a few chain cactus and studied quite a few molecular descriptor in [1]lately. For further research on cactus diagrams, we kindly refer the reader to [2][3][4][5] This article examines the mathematical properties of the general Zagreb indices and their special cases of the line diagrams of ortho cactus and para cactus chains, such as the line graph of the triangular chain cactus LðT n Þ, the line graph of the square chain cactus LðS q Þ, and the hexagonal chain cactus LðH o Þ are considered in the document. This article derives some expressions for molecular descriptors based on graph vertex degrees, such as the general Zagreb index, the F-index, the redefined Zagreb index, the first Zagreb index, the second Zagreb index, the general Randic index, and the symmetric division index.
In the same paper [6], the "forgotten topological index" or F-index was defined as In 2003, Ranjini et al. redefined the Zagreb index in [7] and is defined as The symmetric division index of a graph is defined as For further study about indices index, we refer [7][8][9]. In 2011, Azari et al. introduced a generalized version of vertex degree-based topological index, named as generalized Zagreb index or the (a, b)-Zagreb index and is defined as We refer [7][8][9][10][11] for further study about different indices. It is clear that all the topological indices discussed previously, can be obtained from (a, b)-Zagreb index for some particular values of a and b.

Main Results
In this section, we consider line graph of para cacti chain, ortho cacti chain, and rooted product of cycle and path. We first take a line graph of para cacti chain of cycles C p of length q. Suppose line graph of para cacti chain is denoted by LðC q p Þ. In our first theorem, we calculate an exact result of general Zagreb index of line graph of para cacti chain LðC q p Þ. Theorem 1. Let LðC q p Þ be the line graph of para cacti chain of cycles for p ≥ 4, q ≥ 2. Then Z ðxyÞ ½LðC Proof. The order and size of line graph of para cacti chain of cycles LðC q p Þ are p,q, and pq + 4q − 4. The edge set of LðC q p Þ can be partitioned into subsets given in g : where the number of elements of From the definition of general Zagreb index, we have Corollary 2. Let LðC q p Þ be the line graph of para cacti chain of cycles for ðm ≥ 3, n ≥ 2Þ: Then The expressions for different indices about line graph of para squares cactus chain LðS q Þ can be obtained from Theorem 1 by taking p = 4 The representation of LðS q Þ is shown in Figure 1.
Proof. If we take p = 4 in Theorem 1, we have our this result. From Corollary 3, the result obtained for line graph of para chain square cactus is q ≥ 2. The generalized Zagreb index of line graph of para chain hexagenal cactus LðH q Þ can be obtained from the theorem 1 by putting p = 6. The line graph of para chain hexagonal cactus is shown in Figure 2 .From the general result, the following are topological indices for line graph of para chain hexagonal cactus for q ≥ 3.
(ii) Using We have (iii) Formula for geometric arithmetic index We have (iv) Harmonic index Proof. Partition of edge set of LðO n m Þ is given where the number of element in above sets are 2m − 6, 2m − 2, m + n and mn − 5m + 3n + 4, respectively.   Figure 3: Line graph of triangular ortho chain cactus LðT n Þ.

Journal of Chemistry
Corollary 13. G = LðZC k P l Þ is line graph of rooted product of cycle C k and path P l expressions for first, second Zagreb, forgotten, redefined Zagreb, and symmetric division indices are

Conclusion
In this study, the computation of the first Zagreb index, the second Zagreb index, the F-index, the general Randic index, and the redefined Zagreb index has been made, and their comparisons have been drawn with their corresponding ða , bÞ-Zagreb indices for the line graph of the graph obtained by the rooted product of the cycle and the path graphs. A few closed expressions for the general Zagreb index of the line graph of some cactus chain graphs have also been obtained in this research which has also led to some other significant degree base molecular descriptors for some particular values of a and b. The Zagreb indices of line graphs of some other graph structures can also be calculated for further investigation.

Data Availability
No data were used to support this study.

Conflicts of Interest
The authors declare that they have no conflicts of interest.