A View of Banhatti and Revan Indices in Chemical Graphs

A special type of graph invariant called topological index is the collection of data on algebraic graphs and provides a mathematical way to understand chemical structural features. One of the driving factors behind the wide public attention according to these indices is their remarkable ability to correlate and predict the properties of a wide range of molecular species. Our concern is basically with the study of molecular structures, its shapes, geometries, number of atoms, vertices, bond length, and bond strength. It is very expensive to nd the properties of compounds in laboratories due to dierent expensive apparatus and expensive rare material. It is also time consuming and requires an expert person to perform the experiments. So with the help of graphs and topological index, we want to give an easy approach to nd the dierent characteristics of molecular structures with practical lab experiments. It is a mathematical and theoretical method to estimate the physicochemical properties. Many physicochemical features of a molecular compound can be predicted using topological indices. In this article, we will determine some topological invariants of silicon carbide SiC3–I[t, u] for all values of t and u.


Introduction
Chemical graph theory is a eld of mathematical chemistry that has a signi cant impact on the advancement of the chemical sciences. Physicochemical aspects of chemical compounds are frequently characterized in chemical science using molecular-based structural descriptors, also known as graph indices or topological indices; see [1,2] for graph indices. A chemical graph is a graph in which chemical bonds are portrayed as edges and atoms of a molecule and are portrayed as vertices.
Chemical theory is a branch of graph theory concerned with the discovery of topological indices of chemical graphs that are closely correlated with the chemical properties of chemical compounds. A topological index is a statistical indicator constructed empirically from the network structure. Topological indices have been proven to be e ective for assessing correlations between the structure of a molecular compound and its physical characteristics or bioactivities [3][4][5][6][7][8][9][10]. Topological indices are a practical way to convert chemical composition into numerical values that can be utilized in QSPR and QSAR (quantitative-structure property relationship and quantitative-structure activity relationship, respectively) studies to correlate with physical attributes.
In recent years, the application of graph invariant in QSPR and QSAR investigations has piqued desire. e study of topological indices is extremely important in nanotechnology and theoretical chemistry. Topological indices have been used in chemistry, physics, mathematics, informatics, biology, and other elds [11,12]. Many topological descriptors were introduced in the latter decades of the 20 th century to meet the needs of chemists [13,14]. e structure utilized in this manuscript is a special isomer of silicon carbide. Silicon carbide has a tetrahedral structure. It is an important gradient for host-guest reaction. It is used in bullet proof jackets, car breaks, LED lights, jewelry, and detectors. Revan and Banhatti indices have a very good correlation with many properties of SiC 3 -I [t, u].
Kulli is an Indian mathematician who proposed the Banhatti indices by inspiring the Zagreb indices given by Milan Randic in 1972. Kulli proposed a series of papers on  Banhatti indices and gave their different approaches like  modified and hyper-Banhatti indices.  ese indices give  excellent correlation with the characteristics of different  chemical and nonchemical graphs. ese indices are also helpful in the field of fuzzy mathematics for the study of derived networks [15,16]. A digital world cannot be imagined without silicon. e discovery of silicon is the great revolution in electronics. Zhao and Zahid explored the structure of silicon with the help of Banhatti and Revan indices [17]. Kulli proposed many papers to study oxide networks, honeycomb networks, drugs, and antibiotic structures with the help of Revan and Banhatti indices [18][19][20].

Basic Definitions.
In this paper, we indicate a simple connected graph by Γ. e shortest distance between ω and ] is B( ω, υ). e degree of a vertex ω in graph Γ is denoted by B(ω), an edge between the vertices ω and υ is denoted by e � ωυ, and the degree of an edge "e" is denoted by B(e), where B(e) � B(ω) + B(υ)-(2) and the maximum and minimum degree in a graph is represented by B(Γ) an d δ(Γ) .
We discuss some definitions, and then by utilizing these definitions we can calculate the values of topological indices.
Kulli et al. introduced the first k-Banhatti index B 1 (Γ) and second k-Banhatti index B 2 (Γ) in 2016 [21], mathematically defined as follows: (1) In 2020, Kulli checked out the correlation coefficient for chloroquine and hydroxylchloroquine that is used in the pharmaceutical treatment of coronavirus disease 2019. So he mathematically gave the solution to the problem without doing any experiment in the lab. He just deeply studies the structure of medicine and gives information about it by using the Banhatti index [22]. It is the beauty of TIs that we can mathematically estimate the solution to a problem in any field related to graphs or molecular structure. Kulli et al. defined the modified form of first k-Banhatti index ɱ B 1 (Γ) and second k-Banhatti index ɱ B 2 (Γ) in 2018 [23]. Mathematically, these are determined as follows: Tang and Abid utilize these indices to discuss molecular networks [24].

2D Silicon Carbide
Silicon carbide, commonly referred to as carborundum, is a semiconductor. Silicones are semiconductors that are used in the assembly of a variety of materials. It is an organism that is found in almost all of today's electrical devices. Silicon, like carbon, has a two-dimensional allotrope with a honeycomb pattern, abbreviated as silicone. Untainted 2D carbon monolayergraphene, untainted 2D silicon monolayer-silicon, and 2D silicon-carbon (SiC) monolayer can be considered as a tuneable compound. A great deal of effort have gone into predicting the most stable configurations of the SiC sheet. e cardinality of a vertex set SiC 3 -I [t, u] is 8tu and the cardinality of an edge set is 12tu-2t-3u. To construct the topological indices for this chemical composition, we divide the vertex set and edge set into subdivisions. Let t, u≥1. e vertex is divided into three groups that relying on thevertices of the degree. Graphical representation of 2D silicon-carbide SiC 3 -I[t, u] is shown in Figures 1-4.

Edge Partition.
e silicon carbide structure has five different sets of edges. e first division of edges consist of just two edges ωυ, where Ƌ(ω) � 1 and Ƌ(υ) � 2. e second type of set is composed of one edge ωυ, where Ƌ(ω) � 1and Ƌ(υ) � 3. ere are 3t+2u-3 edges in the third pack of edges Degrees of these edges are also given in Table 1.

Vertex Partition.
e degree of a vertex is the number of edges attached to a vertex. e vertex division is degreebased and has three types of vertices, as given in Table 2. By utilizing this table, we can find many TIs related to the vertex degree.

Techniques and Methods.
We use various methods to calculate TIs, like combinatorial computation, the neighborhood degree counting technique, the vertex degree method, and the edge partition method. For the generalization and verification of calculations, we utilize Matlab. We use Mathematica and Maple for drawing 3D graphs. e Chemsketch is helpful for drawing the chemical graphs of silicon. Special software named SPSS is used for correlation analysis.

Numerical and Graphical Representation
e numerical results of the above calculated topological descriptors for SiC 3 -I [t, u] are represented in this section. e numerical representation are shown in Table 3. A diagram shows a system of relationships between variable quantities using dots to represent the points of the system or using lines to represent the relations of continuous variables.
ere are many types of graphs according to the nature of data.
e graphs used in this article are 3D because of two variables. e variation in data can be checked out by just discussing numerical values, but for a clear comparison of different TIs, graphs are the best way. Graphs are easy to understand, and so it clearly saves time, but we must have enough knowledge about variables and slopes to use them.
Using various values of t and u, we produced numerical  Figures 5-9. e values of all TIs increase when we increase the values of their parameters. e rate of variation of the rst and second k-B-index is higher than that of the other TIs. ese indices have a correlation with many properties in networking and chemistry. e computed topological descriptors increase in proportion to the rise in t and u.
Graphical representation of above calculated topological indices. ese graphs show the variation in the values of TIs with the change of input parameters.

Applications
e Banhatti and Revan indices have a very good correlation with di erent physical and chemical properties of di erent structures. Asthma drugs are also useful for the treatment of COVID-19. e rst Banhatti index has a correlation coe cient r 0.974 with molar volume, and the second Banhatti index is correlated with the boiling point (r 0.9192) and enthalpy (r 0.9125) of these drugs. Hyper-Revan indices are e ective to describe the molar volume of asthma drugs. Both these indices have a correlation with the di erent properties of silicon carbide structures discussed in this manuscript. ese indices also tell us about the structural properties of linear alkanes.

Conclusion
is analysis delves into the multiplicative and degree-based topological indices for SiC 3 -I [t, u]. Silicon carbide is a compulsory part of almost every electronic device. Due to the great applications and functions, we try to understand the structure of it. To explore the structure, we applied many indices and saw the correlation of these indices with many important properties of SiC. In this article, we evaluate the     Journal of Mathematics B 1 (Γ), B 2 (Γ), ɱ B 1 (Γ), ɱ B 2 (Γ), ηB 1 (Γ), ηB 2 (Γ), ηŔ 1 (Γ), ηŔ 2 (Γ),Ŕ 1 (Γ), andŔ 3 (Γ) for Silicon Carbide SiC 3 -I [t, u]. Our discoveries could assist the understanding of silicon-physical carbon's properties, chemical stability, and bioactivities.

Data Availability
No data were used to support this study.

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