The 3-restricted edge-connectivity of the direct product graphs
Abstract
An edge subset \( S ⊂eq E(G) \) is called a 3-restricted edge-cut if \( G - S \) is disconnected and each component of \( G - S \) contains at least three vertices. The 3-restricted edge-connectivity of a graph \( G \), denoted by \( λ3(G) \), is defined as the minimum cardinality among all 3-restricted edge-cuts if there are at least one; otherwise, \( λ3(G) = +∞ \). It is proved that λ3(G)≤3(G) if G has a 3-restricted edge-cut, where 3(G) = \ |[X, V(G) X]G|:|X| = 3 and G[X] is connected \. If \( λ3(G) = 3(G) \), then \( G \) is said to be maximally 3-restricted edge-connected. The direct product of two graphs G and H, denoted by G × H, is defined as the graph with vertex set \( V(G × H) = V(G) × V(H) \), where two vertices \( (u1, v1) \) and \( (u2, v2) \) are adjacent in \( G × H \) if and only if \( u1u2 ∈ E(G) \) and \( v1v2 ∈ E(H) \). In this paper, we determine, for a regular connected graph \( G\), the 3-restricted edge-connectivity of \( G × Cn \), \( G × Kn \) and \( G × Tn \), where \( Cn \), \( Kn \) and \( Tn \) are the cycle, the complete graph and the total graph with \( n \) vertices, respectively. As corollaries, we establish sufficient conditions for the direct product graphs \( G × Cn \), \( G × Kn \) and \( G × Tn \) to be maximally 3-restricted edge-connected.
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