On the tree cover number and the positive semidefinite maximum nullity of a graph

Abstract: For a simple graph $G=(V,E),$ let $\mathcal{S}+(G)$ denote the set of real positive semidefinite matrices $A=(a{ij})$ such that $a_{ij}\neq 0$ if ${i,j}\in E$ and $a_{ij}=0$ if ${i,j}\notin E$. The maximum positive semidefinite nullity of $G$, denoted $\operatorname{M}+(G),$ is $\max{\operatorname{null}(A)|A\in \mathcal{S}+(G)}.$ A tree cover of $G$ is a collection of vertex-disjoint simple trees occurring as induced subgraphs of $G$ that cover all the vertices of $G$. The tree cover number of $G$, denoted $T(G)$, is the cardinality of a minimum tree cover. It is known that the tree cover number of a graph and the maximum positive semidefinite nullity of a graph are equal for outerplanar graphs, and it was conjectured in 2011 that $T(G)\leq M_+(G)$ for all graphs [Barioli et al., Minimum semidefinite rank of outerplanar graphs and the tree cover number, $ Elec. J. Lin. Alg.,$ 2011]. We show that the conjecture is true for certain graph families. Furthermore, we prove bounds on $T(G)$ to show that if $G$ is a connected outerplanar graph on $n\geq 2$ vertices, then $\operatorname{M}+(G)=T(G)\leq \left\lceil\frac{n}{2}\right\rceil$, and if $G$ is a connected outerplanar graph on $n\geq 6$ vertices with no three or four cycle, then $\operatorname{M}+(G)=T(G)\leq \frac{n}{3}$. We also characterize connected outerplanar graphs with $\operatorname{M}_+(G)=T(G)=\left\lceil\frac{n}{2}\right\rceil.$