A Comparison Study of Irregularity Descriptors of Benzene Ring Embedded in P-Type Surface Network and Its Derived Network

Topological indices are atomic auxiliary descriptors which computationally and hypothetically portray the natures of the basic availability of nanomaterials and chemical mixes, and henceforth, they give faster techniques to look at their exercises and properties. Anomaly indices are for the most part used to describe the topological structures of unpredictable graphs. Graph anomaly examines are helpful not only for quantitative structure-activity relationship (QSAR) and also quantitative structure-property relationship (QSPR) but also for foreseeing their diﬀerent physical and compound properties, including poisonousness, obstruction, softening and breaking points, the enthalpy of vanishing, and entropy. In this article, we discuss the irregularities of benzene ring and its line graph and compare them by its irregularity indices. We present graphical comparison by using Mathematica.


Introduction
Let G � (V(G), E(G)) be a simple, finite, and undirected graph, where V(G) and E(G) are the sets containing vertices and edges of G independently. Let du imply the degree of a vertex v and uv address an edge between the two vertices u and v. For defined phrasings, we insinuate [1]. A graph is regular, if all its vertices have the same degree, else it is irregular. A line graph is represented by L(G) and defined as edges of G taken as vertices of L(G), and if two edges of G have a common vertex, then edge is made between vertices of L(G). In history, Paul Erdos conducted the examination of irregular graphs for the first time [2]. Beginning now and into the not-so-distant future, the irregularity degree and irregular graphs have turned into the major open issue of graph theory. A graph should be perfect if all the vertices have different degrees (for instance, no two vertices have the same degree). No graph is perfect shown in [3]. e graphs lying inbetween are called semiperfect (quasiperfect) [4]. A disentangled methodology is the irregularity index for passing on the irregularity. Such irregularity index was introduced in [5]. e Albertson index, AL(G), was characterized by Alberston in [6] as AL(G) � uv∈E(G) |d u − dv|. e irregularity index, IRL(G) and IRLU(G), is characterized by Vukicevic [7] as IRL(G) � Recently, Abdoo et al. established the new form "total irregularity measure of a graph G," which is described in [8][9][10].
e Randic index is defined as In 1985, C 60 was discovered, and after that, study of carbon nanostructures is also the family of nanotechnology. Mackay and Terrones gave new idea by constructing solid carbon with three-dimension frames in 1991 [11]. In the same year, Lenosky et al. [12] proposed a three-dimensional structure by unit cell of 192 atoms and 216 atoms. Later on, Keeffe et al. compared six-folded and eight-folded ring structures' energies in 1992 [13], the second one 3D benzene structure was called 6.82P (polybenzene). In 2018, Ahmad found degree-based topological indices of benzene ring embedded in the P-type surface in the 2D network [14]. Later, in 2019, Yang determined M-polynomial and topological indices of benzene ring embedded in the P-type surface in the 2D network [15]. In the same year, Ahmad et al. computed degree-based topological indices of line graph of benzene ring embedded in the P-type surface in the 2D network [16], and recently, in 2020, Prosanta Sarkar et al. found general fifth M-Zagreb polynomials of benzene ring implanted in the P-type-surface in the 2D network [17].

Methodology
denotes vertices and E(G) denotes edges. In irregularity indices, we first find the order (number of vertices of graph) and size (number of edges of graph) of the graph and partition vertices by its degrees (same and different) and divide edges by its end vertices degree which is usually known as edge partition. We use edge partition as well as order and size to find irregularity indices and edge partition depending on the degree of end vertices of edges.

Results for Benzene Ring Embedded in P-Type Surface
Network. In this section, we compute some irregularity indices of benzene ring such as variance index, Albertson index, and Randic index. Benzene ring embedded in the P-type surface network having 24pq vertices and 32pq − 2q − 2p edges is depicted in Figure 1.
Proof. e order of graph is n � |V(BR[p, q])| � 24pq, and its size is m � |E(BR[p, q])| � 32pq − 2q − 2p. e vertex set of BR[p, q] can be divided into following classes by means of degrees: e edge set of BR[p, q] can be divided into following classes with respect to the degree of end vertices.
And, the cardinality of edges are as follows: First, we find some topological indices which will be used in irregularity indices:

Results for Line Graph of Benzene Ring Embedded in the P-Type Surface Network.
In this section, we compute some irregularity indices of the line graph of the benzene ring network such as variance index, Albertson index, and Randic index. e line graph of benzene ring embedded in the P-type surface network having 32pq − 2q − 2p vertices and � 56pq − 8q − 8p edges is depicted in Figure 2.

Theorem 2. For the block shift network (L(BR[p, q])), we have
Proof. e order of the graph is n � |V(L(BR[p, q]))| � 32pq − 2q − 2p, and its size is e vertex set of L(BR[p, q]) can be divided into the following classes by means of degrees: e edge set of L(BR[p, q]) can be divided into the following classes with respect to the degree of end vertices:   Journal of Mathematics And, the cardinality of edges are as follows: First, we find some topological indices which will be used in irregularity indices:

Graphical Comparison and Conclusion
In this section, we compare irregularity indices of benzene ring and line of benzene ring. Here, we plot characteristics that decide the properties of BR[p, q] with parameters p and q. us, we can conclude the properties of benzene and line of benzene ring on the basis of parameters p and q. Figure 3 shows the variances of both plots which are increasing and parallel. Figures 4-6 depict the same behavior of AL, IR1, and IRLU, as BR[p, q] is more rapid than L(BR[p, q]), but one can see Figure 5 is more sharp than remaining. Figure 7 incorporates the plotting of IR1 which is overlapped by increasing the values of p and q. e behavior of IRA and IRL of BR[p, q] are the same in Figures 8 and 9, but the  behavior of L(BR [p, q]) is much slower than all other irregularity indices. In this paper, we have registered a few degree-based irregularity indices. It is demonstrated that topological indices help to foresee numerous properties without heading off to the wet lab.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

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