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A spanning tree without a vertex of degree two is called a Hist which is an abbreviation for homeomorphically irreducible spanning tree. We provide a necessary condition for the existence of a Hist in a cubic graph. As one consequence, we…

Combinatorics · Mathematics 2017-06-13 Arthur Hoffmann-Ostenhof , Kenta Noguchi , Kenta Ozeki

The essential requirement for a cubic graph to be called a snark is that it can not be edge-coloured with three colours. To avoid trivial cases, varying restrictions on the connectivity are imposed. Snarks are not only interesting in…

Combinatorics · Mathematics 2026-03-19 Gunnar Brinkmann , Steven Van Overberghe

Let $G$ be a cubic graph which has a decomposition into a spanning tree $T$ and a $2$-regular subgraph $C$, i.e. $E(T) \cup E(C) = E(G)$ and $E(T) \cap E(C) = \emptyset$. We provide an answer to the following question: which lengths can the…

Combinatorics · Mathematics 2018-10-09 Arthur Hoffmann-Ostenhof , Thomas Jatschka

For a connected graph $G$, a spanning tree $T$ of $G$ is called a homeomorphically irreducible spanning tree (HIST) if $T$ has no vertices of degree 2. Albertson {\em et al.} proved that it is $NP$-complete to decide whether a graph…

Combinatorics · Mathematics 2025-09-03 Bingqian Gao , Huiqing Liu , Jing Zhao

A tree $t$-spanner of a graph $G$ is a spanning tree of $G$ such that the distance between pairs of vertices in the tree is at most $t$ times their distance in $G$. Deciding tree $t$-spanner admissible graphs has been proved to be tractable…

Discrete Mathematics · Computer Science 2018-01-01 Ioannis Papoutsakis

A vertex of degree one in a tree is called an end vertex and a vertex of degree at least three is called a branch vertex. For a graph $G$, let $\sigma_2$ be the minimum degree sum of two nonadjacent vertices in $G$. We consider tree…

Combinatorics · Mathematics 2015-05-19 Zhora Nikoghosyan

A {\em snark} is a cubic cyclically 4-edge connected graph with edge chromatic number four and girth at least five. We say that a graph $G$ is {\em odd 2-factored} if for each 2-factor F of G each cycle of F is odd. In this paper, we…

Combinatorics · Mathematics 2015-01-13 M. Abreu , D. Labbate , R. Rizzi , J. Sheehan

In graph theory, a Snark is a connected, bridgeless, Cubic graph that cannot be edge-colored with only three colors. Additionally, to avoid some trivial cases, a Snark is typically required to have a girth of minimum five and a cyclic…

Combinatorics · Mathematics 2025-11-13 Bansari. J. Rayjada , Jekil. A. Gadhiya , Mahadityasinh. A. Sarvaiya

For an integer $k\geq 2$, a spanning tree of a graph without vertices of degree from $2$ to $k$ is called a {\it $[2,k]$-ST} of the graph. The concept of $[2,k]$-STs is a natural extension of a homeomorphically irreducible spanning tree (or…

Combinatorics · Mathematics 2025-06-05 Michitaka Furuya , Shoichi Tsuchiya

A snark is a bridgeless cubic graph which is not 3-edge-colourable. The oddness of a bridgeless cubic graph is the minimum number of odd components in any 2-factor of the graph. Lukot'ka, M\'acajov\'a, Maz\'ak and \v{S}koviera showed in…

Combinatorics · Mathematics 2018-04-30 Jan Goedgebeur

In a given graph, a HIST is a spanning tree without $2$-valent vertices. Motivated by developing a better understanding of HIST-free graphs, i.e. graphs containing no HIST, in this article's first part we study HIST-critical graphs, i.e.…

Combinatorics · Mathematics 2025-06-05 Jan Goedgebeur , Kenta Noguchi , Jarne Renders , Carol T. Zamfirescu

The oddness of a cubic graph is the smallest number of odd circuits in a 2-factor of the graph. This invariant is widely considered to be one of the most important measures of uncolourability of cubic graphs and as such has been repeatedly…

Combinatorics · Mathematics 2019-01-31 Jan Goedgebeur , Edita Máčajová , Martin Škoviera

We estimate the minimum number of vertices of a cubic graph with given oddness and cyclic connectivity. We prove that a bridgeless cubic graph $G$ with oddness $\omega(G)$ other than the Petersen graph has at least $5.41\cdot\omega(G)$…

Discrete Mathematics · Computer Science 2012-12-18 Robert Lukotka , Edita Macajova , Jan Mazak , Martin Skoviera

We describe two new algorithms for the generation of all non-isomorphic cubic graphs with girth at least $k\ge 5$ which are very efficient for $5\le k \le 7$ and show how these algorithms can be efficiently restricted to generate snarks…

Combinatorics · Mathematics 2017-06-28 Gunnar Brinkmann , Jan Goedgebeur

In this paper we further our understanding of the structure of class two cubic graphs, or snarks, as they are commonly known. We do this by investigating their 3-critical subgraphs, or as we will call them, minimal conflicting subgraphs. We…

Combinatorics · Mathematics 2022-01-20 Imran Allie

A graph $G=(V,E)$ is said to be odd (or even, resp.) if $d_G(v)$ is odd (or even, resp.) for any $v\in V$. Trivially, the order of an odd graph must be even. In this paper, we show that every 4-edge connected graph of even order has a…

Combinatorics · Mathematics 2025-03-25 Jingyu Zheng , Baoyindureng Wu

A spanning tree of a graph without no vertices of degree $2$ is called a {\it homeomorphically irreducible spanning tree} (or a {\it HIST}) of the graph. Albertson, Berman, Hutchinson and Thomassen~[J. Graph Theory {\bf 14} (1990),…

Combinatorics · Mathematics 2024-08-12 Michitaka Furuya , Akira Saito , Shoichi Tsuchiya

For a given snark G and edge e of G, we can form a cubic graph G_e using an operation we call "edge subtraction". The number of 3-edge-colourings of G_e is 18 * \psi(G,e) for some nonnegative integer \psi(G,e). Given snarks G_1 and G_2, we…

Combinatorics · Mathematics 2013-04-22 Scott A. McKinney

We consider cubic graphs formed with $k \geq 2$ disjoint claws $C_i \sim K_{1, 3}$ ($0 \leq i \leq k-1$) such that for every integer $i$ modulo $k$ the three vertices of degree 1 of $\ C_i$ are joined to the three vertices of degree 1 of…

Discrete Mathematics · Computer Science 2014-05-16 Jean-Luc Fouquet , Henri Thuillier , Jean-Marie Vanherpe

Let $K_k$, $C_k$, $T_k$, and $P_{k}$ denote a complete graph on $k$ vertices, a cycle on $k$ vertices, a tree on $k+1$ vertices, and a path on $k+1$ vertices, respectively. Let $K_{m}-H$ be the graph obtained from $K_{m}$ by removing the…

Combinatorics · Mathematics 2010-02-06 Chunhui Lai , Lili Hu
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