The eccentric connectivity coindex has recently been introduced (Hua and Miao, 2019) as the total Eccentricity sum of all pairs of non-adjacent vertices in a graph. Considering the total Eccentricity product of non-adjacent vertex pairs, we introduce here another invariant of connected graphs called the second Zagreb Eccentricity coindex. We study some mathematical properties of the eccentric connectivity coindex and second Zagreb Eccentricity coindex. We also determine the extremal values of the second Zagreb Eccentricity coindex over some specific families of graphs such as trees, unicyclic graphs, connected graphs, and connected bipartite graphs and describe the extremal graphs. Moreover, we compare the second Zagreb Eccentricity coindex with the eccentric connectivity coindex and give directions for further studies.

The concept of average degree-Eccentricity matrix ADE(G) of a connected graph G is introduced. Some coefficients of the characteristic polynomial of ADE(G) are obtained, as well as a bound for the eigenvalues of ADE(G). We also introduce the average degree-Eccentricity graph energy and establish bounds for it.

We introduce the Laplacian sum-Eccentricity matrix LSe of a graph G, and its Laplacian sum-Eccentricity energy LSeE = Pn i=1 j ij, where  i =  i 􀀀 2m n and where  1;  2; : : :;  n are the eigenvalues of LSe. Upper bounds for LSeE are obtained. A graph is said to be twinenergetic if Pn P i=1 j ij = n i=1 j ij. Conditions for the existence of such graphs are established.

One of the most important ideas employed in chemical graph theory is that of so-called topologicalindices. This is to associate a numerical value with a graph structure that often has some kind ofcorrelation with corresponding chemicals properties. In this paper, we consider some infinitefamilies of 3-fence graphs, namely, ladder, circular ladder and Mobius ladder. We compute someof the Eccentricity based topological indices of these graphs and their line graphs.

The energy of a graph G is equal to the sum of absolute values of the eigenvalues of the adjacency matrix of G, whereas the Laplacian energy of a graph G is equal to the sum of the absolute value of the difference between the eigenvalues of the Laplacian matrix of G and average degree of the vertices of G. Motivated by the work from Sharafdini and Panahbar [R. Sharafdini, H. Panahbar, Vertex weighted Laplacian graph energy and other topological indices, J. Math. Nanosci. 6 (2016) 57 􀀀 65], in this paper we investigate the Eccentricity version of Laplacian energy of a graph G.

The second Zagreb coindex is a well-known graph invariant defined as the total degree product of all non-adjacent vertex pairs in a graph. The second Zagreb Eccentricity coindex is defined analogously to the second Zagreb coindex by replacing the vertex degrees with the vertex eccentricities. In this paper, we present exact expressions or sharp lower bounds for the second Zagreb Eccentricity coindex of some graph products such as lexicographic product, generalized hierarchical product, and strong product. Results are applied to compute the values of this Eccentricity-based invariant for some chemical graphs and nanostructures such as hexagonal chain, linear phenylene chain, and zig-zag polyhex nanotube.

‎The second multiplicative Zagreb Eccentricity index $E^{*}_{2} ({G})$ of a simple connected‎ graph $G$ is expressed as the product of the weights‎ $\varepsilon_{G}(a)\varepsilon_{G}(b)$ over all edges $ab$ of $G$‎, where $\varepsilon_{G}(a)$ stands for the‎ Eccentricity of the vertex $a$ in $G$‎. ‎In this‎ paper‎, ‎some extremal problems on the $E^{*}_{2}$ index over some special graph classes including‎ trees‎, ‎unicyclic graphs and bicyclic graphs are examined‎, ‎and‎ ‎the corresponding extremal graphs are characterized‎. ‎Besides‎, ‎the relationships between this vertex-Eccentricity-based graph invariant and some well-known parameters of graphs and existing graph invariants such as the number of vertices‎, ‎number of edges‎, ‎minimum vertex degree‎, ‎maximum vertex degree‎, ‎eccentric connectivity index‎, ‎connective Eccentricity index‎, ‎first multiplicative Zagreb Eccentricity index and second multiplicative Zagreb index are investigated‎.