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<rdf:RDF xmlns:rdf="http://www.w3.org/1999/02/22-rdf-syntax-ns#" xmlns:dc="http://purl.org/dc/elements/1.1/"><rdf:Description rdf:about="https://repozitorij.uni-lj.si/IzpisGradiva.php?id=168564"><dc:title>On regular graphs with Šoltés vertices</dc:title><dc:creator>Bašić,	Nino	(Avtor)
	</dc:creator><dc:creator>Knor,	Martin	(Avtor)
	</dc:creator><dc:creator>Škrekovski,	Riste	(Avtor)
	</dc:creator><dc:subject>Šoltés problem</dc:subject><dc:subject>Wiener index</dc:subject><dc:subject>regular graphs</dc:subject><dc:subject>cubic graphs</dc:subject><dc:subject>Cayley graph</dc:subject><dc:subject>Šoltés vertex</dc:subject><dc:description>Let $W(G)$ be the Wiener index of a graph $G$. We say that a vertex $v \in V(G)$ is a Šoltés vertex in $G$ if $W(G - v) = W(G)$, i.e. the Wiener index does not change if the vertex $v$ is removed. In 1991, Šoltés posed the problem of identifying all connected graphs ▫$G$▫ with the property that all vertices of $G$ are Šoltés vertices. The only such graph known to this day is $C_{11}$. As the original problem appears to be too challenging, several relaxations were studied: one may look for graphs with at least $k$ Šoltés vertices; or one may look for $\alpha$-Šoltés graphs, i.e. graphs where the ratio between the number of Šoltés vertices and the order of the graph is at least $\alpha$. Note that the original problem is, in fact, to find all $1$-Šoltés graphs. We intuitively believe that every $1$-Šoltés graph has to be regular and has to possess a high degree of symmetry. Therefore, we are interested in regular graphs that contain one or more Šoltés vertices. In this paper, we present several partial results. For every $r\ge 1$ we describe a construction of an infinite family of cubic $2$-connected graphs with at least $2^r$ Šoltés vertices. Moreover, we report that a computer search on publicly available collections of vertex-transitive graphs did not reveal any $1$-Šoltés graph. We are only able to provide examples of large $\frac{1}{3}$-Šoltés graphs that are obtained by truncating certain cubic vertex-transitive graphs. This leads us to believe that no $1$-Šoltés graph other than $C_{11}$ exists.</dc:description><dc:date>2025</dc:date><dc:date>2025-04-17 10:05:10</dc:date><dc:type>Članek v reviji</dc:type><dc:identifier>168564</dc:identifier><dc:language>sl</dc:language></rdf:Description></rdf:RDF>
