Abstract
The commuting graph of a finite non-abelian group G with center Z(G), denoted by Γc(G), is a simple undirected graph whose vertex set is G∖Z(G), and two distinct vertices x and y are adjacent if and only if xy=yx. Alwardi et al. (Bulletin, 2011, 36, 49-59) defined the common neighborhood matrix CN(G) and the common neighborhood energy Ecn(G) of a simple graph G. A graph G is called CN-hyperenergetic if Ecn(G)>Ecn(Kn), where n=|V(G)| and Kn denotes the complete graph on n vertices. Two graphs G and H with equal number of vertices are called CN-equienergetic if Ecn(G)=Ecn(H). In this paper we compute the common neighborhood energy of Γc(G) for several classes of finite non-abelian groups, including the class of groups such that the central quotient is isomorphic to group of symmetries of a regular polygon, and conclude that these graphs are not CN-hyperenergetic. We shall also obtain some pairs of finite non-abelian groups such that their commuting graphs are CN-equienergetic.
Highlights
Guirao and Aviv GibaliLet G be a simple graph whose vertex set is V (G) = {v1, v2, . . . , vn }
In this paper we give an attempt to answer this problem by considering commuting graphs of finite groups
The following theorem is very useful in order to compute CN-energy of commuting graphs of finite groups
Summary
The common neighborhood eigenvalues are symmetric with respect to the origin for some special class of graphs. In this paper we give an attempt to answer this problem by considering commuting graphs of finite groups. The commuting graph of a finite non-abelian group G with center Z ( G ) is a simple undirected graph whose vertex set is G \ Z ( G ) and two vertices x and y are adjacent if and only if xy = yx.
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