English

Quantum walks on join graphs

Quantum Physics 2023-12-13 v1 Combinatorics

Abstract

The join XYX\vee Y of two graphs XX and YY is the graph obtained by joining each vertex of XX to each vertex of YY. We explore the behaviour of a continuous quantum walk on a weighted join graph having the adjacency matrix or Laplacian matrix as its associated Hamiltonian. We characterize strong cospectrality, periodicity and perfect state transfer (PST) in a join graph. We also determine conditions in which strong cospectrality, periodicity and PST are preserved in the join. Under certain conditions, we show that there are graphs with no PST that exhibits PST when joined by another graph. This suggests that the join operation is promising in producing new graphs with PST. Moreover, for a periodic vertex in XX and XYX\vee Y, we give an expression that relates its minimum periods in XX and XYX\vee Y. While the join operation need not preserve periodicity and PST, we show that UM(XY,t)u,vUM(X,t)u,v2V(X)\big| |U_M(X\vee Y,t)_{u,v}|-|U_M(X,t)_{u,v}| \big|\leq \frac{2}{|V(X)|} for all vertices uu and vv of XX, where UM(XY,t)U_M(X\vee Y,t) and UM(X,t)U_M(X,t) denote the transition matrices of XYX\vee Y and XX respectively relative to either the adjacency or Laplacian matrix. We demonstrate that the bound 2V(X)\frac{2}{|V(X)|} is tight for infinite families of graphs.

Keywords

Cite

@article{arxiv.2312.06906,
  title  = {Quantum walks on join graphs},
  author = {Steve Kirkland and Hermie Monterde},
  journal= {arXiv preprint arXiv:2312.06906},
  year   = {2023}
}

Comments

29 pages

R2 v1 2026-06-28T13:47:52.493Z