On the maximum order of graphs embedded in surfaces

TL;DR

This paper establishes upper bounds on the size of graphs embedded in surfaces with bounded Euler genus, showing they behave like trees for large maximum degree and providing constructions that match these bounds, thus answering a longstanding question.

Contribution

It proves that such embedded graphs have size bounds similar to trees, improving previous results, and constructs graphs that meet these bounds, answering a key open question.

Findings

Graphs embedded in surfaces of bounded genus have size bounds similar to trees.

New upper bounds depend on genus, degree, and diameter, improving previous results.

Constructed graphs match the upper bounds, confirming their tightness.

Abstract

The maximum number of vertices in a graph of maximum degree $\Delta\ge 3$ and fixed diameter $k\ge 2$ is upper bounded by $(1+o(1))(\Delta-1)^{k}$. If we restrict our graphs to certain classes, better upper bounds are known. For instance, for the class of trees there is an upper bound of $(2+o(1))(\Delta-1)^{\lfloor k/2\rfloor}$ for a fixed $k$. The main result of this paper is that graphs embedded in surfaces of bounded Euler genus $g$ behave like trees, in the sense that, for large $\Delta$, such graphs have orders bounded from above by \[begin{cases} c(g+1)(\Delta-1)^{\lfloor k/2\rfloor} & \text{if $k$ is even} c(g^{3/2}+1)(\Delta-1)^{\lfloor k/2\rfloor} & \text{if $k$ is odd}, \{cases}\] where $c$ is an absolute constant. This result represents a qualitative improvement over all previous results, even for planar graphs of odd diameter $k$. With respect to lower bounds, we construct graphs of Euler genus $g$, odd diameter $k$, and order $c(\sqrt{g}+1)(\Delta-1)^{\lfloor k/2\rfloor}$ for some absolute constant $c>0$. Our results answer in the negative a question of Miller and \v{S}ir\'a\v{n} (2005).