Perfect quantum state transfer in weighted paths with potentials (loops) using orthogonal polynomials
Abstract
A simple method for transmitting quantum states within a quantum computer is via a quantum spin chain---that is, a path on vertices. Unweighted paths are of limited use, and so a natural generalization is to consider weighted paths; this has been further generalized to allow for loops (\emph{potentials} in the physics literature). We study the particularly important situation of perfect state transfer with respect to the corresponding adjacency matrix or Laplacian through the use of orthogonal polynomials. Low-dimensional examples are given in detail. Our main result is that PST with respect to the Laplacian matrix cannot occur for weighted paths on vertices nor can it occur for certain symmetric weighted trees. The methods used lead us to a conjecture directly linking the rationality of the weights of weighted paths on vertices, with or without loops, with the capacity for PST between the end vertices with respect to the adjacency matrix.
Keywords
Cite
@article{arxiv.1708.03283,
title = {Perfect quantum state transfer in weighted paths with potentials (loops) using orthogonal polynomials},
author = {Steve Kirkland and Darian McLaren and Rajesh Pereira and Sarah Plosker and Xiaohong Zhang},
journal= {arXiv preprint arXiv:1708.03283},
year = {2019}
}
Comments
16 pages; some minor updates from previous version