Title: Two-state transfer: a generalization of pair and plus state transfer

Abstract: In the study of quantum state transfer, one is interested in being able to transmit a quantum state with high fidelity within a quantum spin network. In most of the literature, the state of interest is taken to be associated with a standard basis vector; however, more general states have recently been considered. Here, we consider a general linear combination of two vertex states, which encompasses the definitions of pair states and plus states in connected weighted graphs. A two-state in a graph $X$ is a quantum state of the form $\mathbf{e}_u+s\mathbf{e}_v$, where $u$ and $v$ are two vertices in $X$ and $s$ is a non-zero real number. If $s=-1$ or $s=1$, then such a state is called a pair state or a plus state, respectively.
In this paper, we investigate quantum state transfer between two-states, where the Hamiltonian is taken to be the adjacency, Laplacian or signless Laplacian matrix of the graph. By analyzing the spectral properties of the Hamiltonian, we characterize strongly cospectral two-states built from strongly cospectral vertices. This allows us to characterize perfect state transfer (PST) between two-states in complete graphs, cycles and hypercubes. We also produce infinite families of graphs that admit strong cospectrality and PST between two-states that are neither pair nor plus states. Using singular values and singular vectors, we show that vertex PST in the line graph of $X$ implies PST between the plus states formed by corresponding edges in $X$. Furthermore, we provide conditions such that the converse of the previous statement holds. As an application, we characterize strong cospectrality and PST between vertices in line graphs of trees, unicyclic graphs and Cartesian products.