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Article

Expected Values of Some Molecular Descriptors in Random Cyclooctane Chains

1
Department of Mathematics, College of Sciences, University of Sharjah, Sharjah 27272, United Arab Emirates
2
Department of Mathematical Science, United Arab Emirates University, Al Ain 15551, United Arab Emirates
*
Authors to whom correspondence should be addressed.
Symmetry 2021, 13(11), 2197; https://doi.org/10.3390/sym13112197
Submission received: 23 October 2021 / Revised: 5 November 2021 / Accepted: 12 November 2021 / Published: 17 November 2021
(This article belongs to the Special Issue Topological Graph Theory and Discrete Geometry)
Figure 1
<p>The cyclooctane chains for <math display="inline"><semantics> <mrow> <mi>m</mi> <mo>=</mo> <mn>1</mn> <mo>,</mo> <mn>2</mn> </mrow> </semantics></math>.</p> ">
Figure 2
<p>The four types of cyclooctane chains for <math display="inline"><semantics> <mrow> <mi>m</mi> <mo>=</mo> <mn>3</mn> </mrow> </semantics></math>.</p> ">
Figure 3
<p>The four types of local arrangements in cyclooctane for <math display="inline"><semantics> <mrow> <mi>m</mi> <mo>&gt;</mo> <mn>3</mn> </mrow> </semantics></math>.</p> ">
Figure 4
<p>Four special cyclooctain chains with <span class="html-italic">m</span> octagons.</p> ">
Figure 5
<p>Difference between <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>A</mi> <mi>Z</mi> <mi>I</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math> and <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>S</mi> <mi>D</mi> <mi>D</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math>.</p> ">
Figure 6
<p>Difference between <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>S</mi> <mi>D</mi> <mi>D</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math> and <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>I</mi> <mi>S</mi> <mi>I</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math>.</p> ">
Figure 7
<p>Difference between <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>a</mi> <msub> <mi>M</mi> <mn>2</mn> </msub> <mo stretchy="false">]</mo> </mrow> </semantics></math> and <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>I</mi> <mi>S</mi> <mi>I</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math>.</p> ">
Figure 8
<p>Difference between <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>A</mi> <mi>Z</mi> <mi>I</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math>, <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>S</mi> <mi>D</mi> <mi>D</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math>, <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>I</mi> <mi>S</mi> <mi>I</mi> <mo stretchy="false">]</mo> </mrow> </semantics></math> and, <math display="inline"><semantics> <mrow> <mi>E</mi> <mo stretchy="false">[</mo> <mi>a</mi> <msub> <mi>M</mi> <mn>2</mn> </msub> <mo stretchy="false">]</mo> </mrow> </semantics></math>.</p> ">
Versions Notes

Abstract

:
The modified second Zagreb index, symmetric difference index, inverse symmetric index, and augmented Zagreb index are among the molecular descriptors which have good correlations with some physicochemical properties (such as formation heat, total surface area, etc.) of chemical compounds. By a random cyclooctane chain, we mean a molecular graph of a saturated hydrocarbon containing at least two rings such that all rings are cyclooctane, every ring is joint with at most two other rings through a single bond, and exactly two rings are joint with one other ring. In this article, our main purpose is to determine the expected values of the aforementioned molecular descriptors of random cyclooctane chains explicitly. We also make comparisons in the form of explicit formulae and numerical tables consisting of the expected values of the considered descriptors of random cyclooctane chains. Moreover, we outline the graphical profiles of these comparisons among the mentioned descriptors.

1. Introduction

Chemical graph theory is a branch of mathematics which deals with the mathematical modeling of graphs that is also an essential branch of theoretical chemistry. Initial chemical research introduced the theory of chemical graphs. Chemists have confirmed that the physicochemical properties of a compound have been associated with molecular arrangement, with results derived from an enormous number of investigational data. Furthermore, the researchers considered the same topological index based on various chemical properties and applied it to QSR/QSPR learning. Generally, the features of a compound derived by chemical experiments are not very authentic. However, theoretical calculations assume a vital role in many extraordinary cases. There are numerous topological indices in the literature of chemical graph theory. The first of its kind is the Wiener index [1]. After that, the most important topological index is the class of the Zagreb indices and its variants [2]. The family of Adriatic indices was introduced in [3,4,5,6]. An especially interesting subclass of these descriptors consists of 148 discrete Adriatic indices. The so-called inverse sum indeg index (ISI) was defined in [4] as a significant predictor of the total surface area of octane isomers. A graph consists of some points (nodes) and lines (edges). Suppose Γ = Γ ( V , E ) is a graph of order n with vertex set V ( Γ ) = { u 1 , u 2 , , u n } and edge set E. Let u i be the node of a graph. Then, the degree of a node is the number of edges incident to that vertex and is denoted by d i . If an edge connects a vertex of degree i and a vertex of degree j in Γ , then we call it an ( i , j ) -edge. Let x i j ( Γ ) denote the number of ( i , j ) -edges in the graph Γ .
A Z I ( Γ ) = u i u j E ( Γ ) ( d i d j d i + d j 2 ) 3
I S I ( Γ ) = u i u j E ( Γ ) d i d j d i + d j
S D D ( Γ ) = u i u j E ( Γ ) d i 2 + d j 2 d i d j
a M 2 ( Γ ) = u i u j E ( Γ ) 1 d i d j
Significant efforts have been made to give an explicit formula for the topological indices for a special family of graphs or chemical graphs; see for example the recent papers [7,8].

2. Materials and Methods

A cyclooctane chain is when every node of a cyclooctane system is in an octagon. We obtain a cyclooctane chain by composing an edge joining octagons. Figure 1 shows the unique RCOC m for m = 1 , 2 , and Figure 2 shows four RCOC m chains for m = 3 . We termed RCOC m + 1 1 , RCOC m + 1 2 , RCOC m + 1 3 , and RCOC m + 1 4 by local adjustment of the cyclooctane chains (see Figure 3). Therefore, RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) can be attained by stepwise addition of a terminal octagon. A random selection ( k = 3 , 4 , , m ) is made at each step from one of the four probable structures:
(i)
RCOC k 1 RCOC k 1 with probability ρ 1 ,
(ii)
RCOC k 1 RCOC k 2 with probability ρ 2 ,
(iii)
RCOC k 1 RCOC k 2 with probability ρ 3 , or
(iv)
RCOC k 1 RCOC k 3 with probability r = 1 ρ 1 ρ 2 ρ 3 .
A process is a zeroth-order Markov process if the probabilities ρ 1 , ρ 2 , ρ 3 are unvarying in step parameter and steady. Several papers are concentrated about random arrangement of graphs. For more details, see [9,10,11,12,13,14,15]. The comparison and inequalities among some indices for molecular graphs have been derived in [16,17]. Around one decade before, the coindex versions of these Zagreb indices were introduced. First, two extremum Zagreb indices and coindices of chemical trees were considered in [18]. In degree-based topological indices, many indices depend on the vertex degree of the molecular graph. Some degree-based topological indices are described for pentagonal chains [19]. Bond incident degree (BID) indices for some nanostructures [20,21], tree-like polyphenylene systems, spiro hexagonal systems and polyphenylene dendrimer nanostars [22] are bounds for the general sum-connectivity index of composite graphs [23]. Some vertex-degree-based topological indices are of cacti [24,25]. The Wiener indices of random benzenoid chain was considered by Gutman et al. [26,27]. In 2012, random polyphenyl chains were studied by Yang and Zhang [28].
A number of papers are attentive regarding the random arrangement of topological indices [29]. Cyclooctanes are a kind of saturated hydrocarbons. For many years, chemists have paid a lot of attention to their derivatives [30,31,32,33]. These derivatives are seen and used in drug synthesis, combustion kinetics, organic synthesis, etc. For example, the osmium-catalysed bis-dihydroxylation of 1,5-cyclooctadiene has utilized cyclooctane 1 , 2 , 5 , 6 tetrol [33]. Alamdari et al. [30] considered the combination of some cyclooctane-based quinoxaline pyrazines. These molecular-like graphs [34,35] are geometric graphs (finite two-connected) bounded by a quadrangles of side length one and a regular octagon.
Note that a class of polycyclic conjugated hydrocarbons with tree-like octagonal systems is represented in [34]. Some mathematicians were attracted by octagonal graphs [36]. The numbers of isomers in tree-like octagonal graphs were expressed by Brunvoll et al. [34]. Yang and Zhao [35] studied the relationship among the numbers in a class of Hosoya index of the caterpillar trees and octagonal graphs.
In this work, we study the expected values of the modified Zagreb, symmetric difference, inverse symmetric, and augmented Zagreb indices in random cyclooctane chain. Furthermore, we give analytic proofs for comparison, along with numerical and graphical profiles of these indices in a random cyclooctane chain.
Here, let us examine the modified Zagreb index, symmetric difference index, inverse symmetric index, and augmented Zagreb index in the chain RCOC m with m octagons. Consider RCOC m to be the cyclooctane chain obtained from RCOC m 1 , as shown in Figure 3. It is easy to see from the structure of the chain RCOC m that it contains only ( 2 , 2 ) , ( 2 , 3 ) , and ( 3 , 3 ) -types of edges. Therefore, to calculate these indices for the chain RCOC m , we need to determine only its edges of types x 22 ( RCOC m ) , x 23 ( RCOC m ) and x 33 ( RCOC m ) . Hence, from Equations (1)–(4), one can write as:
A Z I ( RCOC m ) = 8 x 22 ( RCOC m ) + 8 x 23 ( RCOC m ) + 729 64 x 33 ( RCOC m ) .
I S I ( RCOC m ) = x 22 ( RCOC m ) + 6 5 x 23 ( RCOC m ) + 3 2 x 33 ( RCOC m ) .
S D D ( RCOC m ) = 2 x 22 ( RCOC m ) + 13 6 x 23 ( RCOC m ) + 2 x 33 ( RCOC m ) .
a M 2 ( RCOC m ) = 1 4 x 22 ( RCOC m ) + 1 6 x 23 ( RCOC m ) + 1 9 x 33 ( RCOC m ) .

3. Results

Notice that RCOC m is a random cyclooctane chain due to its local arrangements. Therefore, A Z I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) , a M 2 ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) , I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) and S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) are the random variables. Now, we will calculate the expected values of these indices in RCOC m , and denote these as E m A Z I = E [ A Z I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] , E m a M 2 = E [ a M 2 ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] , E m I S I = E [ I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] , E m S D D = E [ S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] , respectively.
Theorem 1.
Let m 2 and a random cyclooctane chain RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) . Then
E m A Z I = m 64 ( 4825 + 217 ρ 1 ) ρ 1 217 32 729 64 .
Proof. 
Since E 2 A Z I = 8921 64 is correct, then for m 3 , there are 4 types of probabilities (see Figure 3).
(a).
If RCOC m 1 RCOC m 1 with probability ρ 1
x 22 ( RCOC m 1 ) = x 22 ( RCOC m 1 ) + 5 , x 23 ( RCOC m 1 ) = x 23 ( RCOC m 1 ) + 2 and
x 33 ( RCOC m 1 ) = x 33 ( RCOC m 1 ) + 2 , and from (5), we have
A Z I ( RCOC m 1 ) = A Z I ( RCOC m 1 ) + 2521 32 .
(b).
If RCOC m 1 RCOC m 2 with probability ρ 2 , then
x 22 ( RCOC m 2 ) = x 22 ( RCOC m 1 ) + 4 , x 23 ( RCOC m 2 ) = x 23 ( RCOC m 1 ) + 4 and
x 33 ( RCOC m 2 ) = x 33 ( RCOC m 1 ) + 1 , and from (5), we have
A Z I ( RCOC m 2 ) = A Z I ( RCOC m 1 ) + 4825 64 .
(c).
If RCOC m 1 RCOC m 2 with probability ρ 3 , then
x 22 ( RCOC m 3 ) = x 22 ( RCOC m 1 ) + 4 , x 23 ( RCOC m 3 ) = x 23 ( RCOC m 1 ) + 4 and
x 33 ( RCOC m 3 ) = x 33 ( RCOC m 1 ) + 1 , and from (5), we have
A Z I ( RCOC m 2 ) = A Z I ( RCOC m 1 ) + 4825 64 .
(d).
If RCOC m 1 RCOC m 3 with probability 1 ρ 1 ρ 2 ρ 3 , then
x 22 ( RCOC m 4 ) = x 22 ( RCOC m 1 ) + 4 , x 23 ( RCOC m 4 ) = x 23 ( RCOC m 1 ) + 4 and
x 33 ( RCOC m 4 ) = x 33 ( RCOC m 1 ) + 1 , and from (5), we have
A Z I ( RCOC m 3 ) = A Z I ( RCOC m 1 ) + 4825 64 .
Thus, we obtain
E m A Z I = ρ 1 A Z I ( RCOC m 1 ) + ρ 2 A Z I ( RCOC m 2 ) + ρ 3 A Z I ( RCOC m 3 ) + ( 1 ρ 1 ρ 2 ρ 3 ) A Z I ( RCOC m 4 ) = ρ 1 [ A Z I ( RCOC m + 2521 32 ) ] + ρ 2 [ A Z I ( RCOC m + 4825 64 ) ] + ρ 3 [ A Z I ( RCOC m + 4825 64 ) ] + ( 1 ρ 1 ρ 2 ρ 3 ) [ A Z I ( RCOC m ) + 4825 64 ] = A Z I ( RCOC m 1 ) + ρ 1 217 64 + 4825 64 .
E m A Z I = A Z I ( RCOC m 1 ) + ρ 1 217 64 + 4825 64 .
However, E [ E m A Z I ] = E m A Z I ; thus, applying the operator E on (9), we obtain
E m A Z I = E m 1 A Z I + ρ 1 217 64 + 4825 64 , m > 2 ,
and by the recurrence relation (10) using initial conditions, we get
E m A Z I = m 64 ( 4825 + 217 ρ 1 ) ρ 1 217 32 729 64 .
Theorem 2.
Let m 2 and a random cyclooctane chain RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) . Then
E m I S I = m 10 ( ρ 1 + 103 ) 23 10 ρ 1 5 .
Proof. 
Since E 2 R = 183 10 is correct, then for m 3 , there are 4 types of probabilities (see Figure 3).
(a).
If RCOC m 1 RCOC m 1 with probability ρ 1
x 22 ( RCOC m 1 ) = x 22 ( RCOC m 1 ) + 5 , x 23 ( RCOC m 1 ) = x 23 ( RCOC m 1 ) + 2 and
x 33 ( RCOC m 1 ) = x 33 ( RCOC m 1 ) + 2 , and from (6), we have
I S I ( RCOC m 1 ) = I S I ( RCOC m 1 ) + 52 5 .
(b).
If RCOC m 1 RCOC m 2 with probability ρ 2 , then
x 22 ( RCOC m 2 ) = x 22 ( RCOC m 1 ) + 4 , x 23 ( RCOC m 2 ) = x 23 ( RCOC m 1 ) + 4 and
x 33 ( RCOC m 2 ) = x 33 ( RCOC m 1 ) + 1 , and from (6), we have
I S I ( RCOC m 2 ) = I S I ( RCOC m 1 ) + 103 10 .
(c).
If RCOC m 1 RCOC m 2 with probability ρ 3 , then
x 22 ( RCOC m 3 ) = x 22 ( RCOC m 1 ) + 4 , x 23 ( RCOC m 3 ) = x 23 ( RCOC m 1 ) + 4 and
x 33 ( RCOC m 3 ) = x 33 ( RCOC m 1 ) + 1 , and from (6), we have
I S I ( RCOC m 2 ) = I S I ( RCOC m 1 ) + 103 10 .
(d).
If RCOC m 1 RCOC m 3 with probability 1 ρ 1 ρ 2 ρ 3 , then
x 22 ( RCOC m 4 ) = x 22 ( RCOC m 1 ) + 4 , x 23 ( RCOC m 4 ) = x 23 ( RCOC m 1 ) + 4 and
x 33 ( RCOC m 4 ) = x 33 ( RCOC m 1 ) + 1 , and from (6), we have
I S I ( RCOC m 3 ) = I S I ( RCOC m 1 ) + 103 10 .
Thus, we get
E m I S I = ρ 1 I S I ( RCOC m 1 ) + ρ 2 I S I ( RCOC m 2 ) + ρ 3 I S I ( RCOC m 3 ) + ( 1 ρ 1 ρ 2 ρ 3 ) I S I ( RCOC m 4 ) = ρ 1 [ I S I ( RCOC m ) + 52 5 ] + ρ 2 [ I S I ( RCOC m ) + 103 10 ] + ρ 3 [ I S I ( RCOC m ) + 103 10 ] + ( 1 ρ 1 ρ 2 ρ 3 ) [ I S I ( RCOC m ) + 103 10 ]
E m I S I = I S I ( RCOC m 1 ) + ρ 1 1 10 + 103 10 .
However, E [ E m ] H = E m H ; thus, applying the operator E on (11), we obtain
E m I S I = E m 1 I S I + ρ 1 1 10 + 103 10 . m > 2 ,
and by the recurrence relation (12) using initial conditions, we get
E m I S I = m 10 ( ρ 1 + 103 ) 23 10 ρ 1 1 5 .
Theorem 3.
Let m 2 and a random cyclooctane chain RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) . Then
E m S D D = 1 3 [ m ( 56 ρ 1 ) + 2 ρ 1 8 ] .
Proof. 
Since E 2 R = 104 3 is correct, then for m 3 , there are 4 types of probabilities (see Figure 3). Thus, from (7) we get the following:
E m S D D = ρ 1 S D D ( RCOC m 1 ) + ρ 2 S D D ( RCOC m 2 ) + ρ 3 S D D ( RCOC m 3 ) + ( 1 ρ 1 ρ 2 ρ 3 ) S D D ( RCOC m 4 ) = ρ 1 [ S D D ( RCOC m ) + 55 3 ] + ρ 2 [ S D D ( RCOC m ) + 56 3 ] + ρ 3 [ S D D ( RCOC m ) + 56 3 ] + ( 1 ρ 1 ρ 2 ρ 3 ) [ S D D ( RCOC m ) + 56 3 ]
E m S D D = S D D ( RCOC m 1 ) ρ 1 1 3 + 56 3 .
However, E [ E m ] S D D = E m S D D ; thus, applying the operator E on (13), we obtain
E m S D D = E m 1 S D D ρ 1 1 3 + 56 3 . m > 2 ,
and by the recurrence relation (16) using initial conditions, we get
E m S D D = 1 3 [ m ( 56 ρ 1 ) + 2 ρ 1 8 ] .
 □
Theorem 4.
Let m 2 and a random cyclooctane chain RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) . Then
E m a M 2 = m [ 16 9 + ρ 1 36 ] ρ 1 18 + 2 9 .
Proof. 
Since E 2 a M 2 = 34 9 is correct, then for m 3 , there are 4 types of probabilities (see Figure 3). Thus, from (8), we get the following:
E m a M 2 = ρ 1 a M 2 ( RCOC m 1 ) + ρ 2 a M 2 ( RCOC m 2 ) + ρ 3 a M 2 ( RCOC m 3 ) + ( 1 ρ 1 ρ 2 ρ 3 ) a M 2 ( RCOC m 4 ) = ρ 1 [ a M 2 ( RCOC m ) + 65 36 ] + ρ 2 [ a M 2 ( RCOC m ) + 16 9 ] + ρ 3 [ a M 2 ( RCOC m ) + 16 9 ] + ( 1 ρ 1 ρ 2 ρ 3 ) [ a M 2 ( RCOC m ) + 16 9 ]
E m a M 2 = a M 2 ( RCOC m 1 ) + ρ 1 1 36 + 16 9 .
However, E [ E m ] a M 2 = E m a M 2 ; thus, applying the operator E on (15), we obtain
E m a M 2 = E m 1 a M 2 + ρ 1 1 36 + 16 9 . m > 2 ,
and by the recurrence relation (16) using initial conditions, we get
E m a M 2 = m [ 16 9 + ρ 1 36 ] ρ 1 18 + 2 9 .
We now turn our attention to the special cyclooctane chains CO m , CZ m , CM m and CL m , as shown in Figure 4. These chains can also be obtained as CO m = RCOC ( m ; 1 , 0 , 0 ) , CM m = RCOC ( m ; 0 , 1 , 0 ) , CZ m = RCOC ( m ; 0 , 0 , 1 ) , and CL m = RCOC ( m ; 0 , 0 , 0 ) . Then, we can easily calculate these indices for these four special chains by using Theorems 1–4.
Corollary 1.
For m 2 , we have the following:
1. 
  • A Z I ( CO m ) = 2521 32 m 1163 64 .;
  • I S I ( CO m ) = 52 5 m 5 2 ;
  • S D D ( CO m ) = 1 3 [ 55 m 6 ] ;
  • a M 2 ( CO m ) = 65 36 m + 1 6 .
2. 
  • A Z I ( CZ m ) = A Z I ( CL m ) = A Z I ( CM m ) = 1 64 [ 4825 m 729 ] ;
  • I S I ( CM m ) = I S I ( CZ m ) = I S I ( CL m ) = 103 10 m 23 10 .;
  • S D D ( CM m ) = S D D ( CZ m ) = S D D ( CL m ) = 1 3 [ 56 m 8 ] ;
  • a M 2 ( CM m ) = a M 2 ( CZ m ) = a M 2 ( CL m ) = 1 9 [ 16 m + 2 ] .

4. Discussion and Conclusions

In this section, we are going to provide an expository comparison between the expected values for the modified Zagreb, symmetric difference, inverse symmetric, and augmented Zagreb indices for arbitrary cyclooctane chains with the same probabilities. At that point, the comparison between the expected values of these indices for diverse values of the probability ρ 1 is given in Table 1, Table 2, Table 3 and Table 4. The augmented Zagreb index is continuously more noteworthy than the other three indices, specifically the modified Zagreb, symmetric difference, and inverse symmetric indices. The graphical profile of the comparison between two indices is given in Figure 5, which recommends that the augmented Zagreb index is always greater than the symmetric difference index. From Figure 6, one can see that the symmetric difference index is continuously greater than the inverse symmetric index, and Figure 7 proposes that the inverse symmetric index is continuously more prominent than the modified Zagreb index. The graphical profile of the comparison between all four indices is given in Figure 8, which suggests that the augmented Zagreb index is always greater than the other indices.
Theorem 5.
If m 2 , then
E [ A Z I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] > E [ S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] .
Proof. 
It is true for m = 2 . Now, let us solve it for m > 2 ; by using Theorems 1 and 3, we have
E [ A Z I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] E [ S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ]
= m 64 ( 4825 + 217 ρ 1 ) ρ 1 217 32 729 64 1 3 [ m ( 56 ρ 1 ) + 2 ρ 1 8 ] = ( m 2 ) [ 10891 192 + ρ 1 715 192 ] + 20107 192 = ( m 2 ) 192 [ 10891 + 715 ρ 1 ] + 20107 192 > 0 m > 2 a n d 0 ρ 1 1 .
Theorem 6.
If m 2 , then
E [ S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] > E [ I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] .
Proof. 
It is true for m = 2 . Now, let us solve it for m > 2 ; by using Theorems 2 and 3, we have
E [ S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] E [ I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ]
= 1 3 [ m ( 56 ρ 1 ) + 2 ρ 1 8 ] [ m 10 ( ρ 1 + 103 ) 23 10 ρ 1 5 ] = ( m 2 ) [ 251 30 ρ 1 13 30 ] + 491 30 = ( m 2 ) 30 [ 251 13 ρ 1 ] + 491 30 > 0 251 13 ρ 1 > 0 , m > 2 a n d 0 ρ 1 1 .
Theorem 7.
If m 2 , then
E [ I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] > E [ a M 2 ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] .
Proof. 
It is true for m = 2 . Now, let us solve it for m > 2 ; by using Theorems 3 and 4, we have
E [ I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] E [ a M 2 ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ]
= m 10 ( ρ 1 + 103 ) 23 10 ρ 1 5 m [ 16 9 + ρ 1 36 ] + ρ 1 18 2 9 = ( m 2 ) [ 767 90 + ρ 1 13 180 ] + 1307 90 = ( m 2 ) 180 [ 1534 + 13 ρ 1 ] + 1307 90 > 0 m > 2 a n d 0 ρ 1 1 .
Theorem 8.
If m 2 , then
E [ A Z I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] > E [ S D D ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] > E [ I S I ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] > E [ a M 2 ( RCOC ( m ; ρ 1 , ρ 2 , ρ 3 ) ) ] .
Proof. 
We may prove this result with the help of Theorems 5–7. □
In this work, we study the expected values of the modified Zagreb, symmetric difference, inverse symmetric, and augmented Zagreb indices in a random cyclooctane chain. Furthermore, we give analytic proofs for comparisons, along with numerical and graphical profiles of these indices in random cyclooctane chains. More precisely, the numerical tables and graphical profiles suggest that the augmented Zagreb index is continuously more noteworthy than the other three indices, specifically the modified Zagreb, symmetric difference, and inverse symmetric indices.

Author Contributions

Conceptualization, Z.R.; methodology, Z.R.; validation, Z.R.; investigation, Z.R. and M.I.; resources, M.I. and Z.R.; writing—original draft preparation, Z.R.; writing—review and editing, Z.R. and M.I.; supervision, Z.R.; funding acquisition, M.I. and Z.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

Muhammad Imran has been supported during the work on this paper by the University program of Advanced Research (UPAR) and UAEU-AUA grants of United Arab Emirates University (UAEU) via Grant No. G00003271 and Grant No. G00003461. Zahid Raza has been supported during the work on this paper by the University of Sharjah under Projects # 2102144098 and # 1802144068 and MASEP Research Group.

Conflicts of Interest

The authors declare no conflict of interest.

References

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Figure 1. The cyclooctane chains for m = 1 , 2 .
Figure 1. The cyclooctane chains for m = 1 , 2 .
Symmetry 13 02197 g001
Figure 2. The four types of cyclooctane chains for m = 3 .
Figure 2. The four types of cyclooctane chains for m = 3 .
Symmetry 13 02197 g002
Figure 3. The four types of local arrangements in cyclooctane for m > 3 .
Figure 3. The four types of local arrangements in cyclooctane for m > 3 .
Symmetry 13 02197 g003
Figure 4. Four special cyclooctain chains with m octagons.
Figure 4. Four special cyclooctain chains with m octagons.
Symmetry 13 02197 g004
Figure 5. Difference between E [ A Z I ] and E [ S D D ] .
Figure 5. Difference between E [ A Z I ] and E [ S D D ] .
Symmetry 13 02197 g005
Figure 6. Difference between E [ S D D ] and E [ I S I ] .
Figure 6. Difference between E [ S D D ] and E [ I S I ] .
Symmetry 13 02197 g006
Figure 7. Difference between E [ a M 2 ] and E [ I S I ] .
Figure 7. Difference between E [ a M 2 ] and E [ I S I ] .
Symmetry 13 02197 g007
Figure 8. Difference between E [ A Z I ] , E [ S D D ] , E [ I S I ] and, E [ a M 2 ] .
Figure 8. Difference between E [ A Z I ] , E [ S D D ] , E [ I S I ] and, E [ a M 2 ] .
Symmetry 13 02197 g008
Table 1. Expected values of indices for p 1 = 1 .
Table 1. Expected values of indices for p 1 = 1 .
m E AZI E SDD E ISI E aM 2
4296.95312571.3333333339.17.333333333
5375.73437589.6666666749.59.138888889
6454.51562510859.910.94444444
7533.296875126.333333370.312.75
8612.078125144.666666780.714.55555556
9690.85937516391.116.36111111
10769.640625181.3333333101.518.16666667
11848.421875199.6666667111.919.97222222
12927.203125218122.321.77777778
131005.984375236.3333333132.723.58333333
Table 2. Expected values of indices for p 1 = 0 .
Table 2. Expected values of indices for p 1 = 0 .
m E AZI E SDD E ISI E aM 2
4290.1718757238.97.333333333
5365.562590.6666666749.29.111111111
6440.953125109.333333359.510.88888889
7516.3437512869.812.66666667
8591.734375146.666666780.114.44444444
9667.125165.333333390.416.22222222
10742.515625184100.718
11817.90625202.666666711119.77777778
12893.296875221.3333333121.321.55555556
13968.6875240131.623.33333333
Table 3. Expected values of indices for p 1 = 1 / 2 .
Table 3. Expected values of indices for p 1 = 1 / 2 .
m E AZI E SDD E ISI E aM 2
4293.562571.66666667397.361111111
5370.648437590.1666666749.359.152777778
6447.734375108.666666759.710.94444444
7524.8203125127.166666770.0512.73611111
8601.90625145.666666780.414.52777778
9678.9921875164.166666790.7516.31944444
10756.078125182.6666667101.118.11111111
11833.1640625201.1666667111.4519.90277778
12910.25219.6666667121.821.69444444
13987.3359375238.1666667132.1523.48611111
Table 4. Expected values of indices for p 1 = 1 / 4 .
Table 4. Expected values of indices for p 1 = 1 / 4 .
m E AZI E SDD E ISI E aM 2
4291.867187571.8333333338.957.347222222
5368.105468890.4166666749.2759.131944444
6444.3437510959.610.91666667
7520.5820313127.583333369.92512.70138889
8596.8203125146.166666780.2514.48611111
9673.0585938164.7590.57516.27083333
10749.296875183.3333333100.918.05555556
11825.5351563201.9166667111.22519.84027778
12901.7734375220.5121.5521.625
13978.0117188239.0833333131.87523.40972222
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Raza, Z.; Imran, M. Expected Values of Some Molecular Descriptors in Random Cyclooctane Chains. Symmetry 2021, 13, 2197. https://doi.org/10.3390/sym13112197

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Raza Z, Imran M. Expected Values of Some Molecular Descriptors in Random Cyclooctane Chains. Symmetry. 2021; 13(11):2197. https://doi.org/10.3390/sym13112197

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Raza, Zahid, and Muhammad Imran. 2021. "Expected Values of Some Molecular Descriptors in Random Cyclooctane Chains" Symmetry 13, no. 11: 2197. https://doi.org/10.3390/sym13112197

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Raza, Z., & Imran, M. (2021). Expected Values of Some Molecular Descriptors in Random Cyclooctane Chains. Symmetry, 13(11), 2197. https://doi.org/10.3390/sym13112197

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