Abstract
A graph $G$ is a non-separating planar graph if there is a drawing $D$ of $G$ on the plane such that (1) no two edges cross each other in $D$ and (2) for any cycle $C$ in $D$, any two vertices not in $C$ are on the same side of $C$ in $D$.
 Non-separating planar graphs are closed under taking minors and are a subclass of planar graphs and a superclass of outerplanar graphs.
 In this paper, we show that a graph is a non-separating planar graph if and only if it does not contain $K_1 \cup K_4$ or $K_1 \cup K_{2,3}$ or $K_{1,1,3}$ as a minor.
 Furthermore, we provide a structural characterisation of this class of graphs. More specifically, we show that any maximal non-separating planar graph is either an outerplanar graph or a wheel or it is a graph obtained from the disjoint union of two triangles by adding three vertex-disjoint paths between the two triangles.
 Lastly, to demonstrate an application of non-separating planar graphs, we use the characterisation of non-separating planar graphs to prove that there are maximal linkless graphs with $3n-3$ edges. Thus, maximal linkless graphs can have significantly fewer edges than maximum linkless graphs; Sachs exhibited linkless graphs with $n$ vertices and $4n-10$ edges (the maximum possible) in 1983.
Highlights
A drawing of a graph in the plane consists of a set of points representing the vertices of the graph and a set of curves between certain pairs of points representing edges between corresponding vertex pairs of the graph where the curves do not pass through the points that represent vertices
Characterisation of outer projective planar graphs in terms of 32 forbidden minors [4];
It is straightforward to see that any outerplanar graph or a subgraph of a wheel or an elongated triangular prism does not contain any of K1 ∪ K4 or K1 ∪ K2,3 or K1,1,3 as a minor
Summary
A drawing of a graph in the plane consists of a set of points representing (under a bijection) the vertices of the graph and a set of curves between certain pairs of points representing edges between corresponding vertex pairs of the graph where the curves do not pass through the points that represent vertices. Sachs observed that for n 4, there exists a linklessly embeddable graph with n vertices and 4n − 10 edges, obtained from a maximal planar the electronic journal of combinatorics 28(1) (2021), #P1.11 graph by adding a vertex adjacent to all other vertices [15]. Since a linklessly embeddable graph does not contain a K6-minor [15], it follows from a theorem of Mader [9] that a linklessly embeddable graph on n 4 vertices has at most 4n − 10 edges This answers the question of Sachs [15].
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