Narrow Results

We study continuous-time quantum walks on graphs which generalize the hypercube. The only known family of graphs whose quantum walk instantaneously mixes to uniform is the Hamming graphs with small arities. We show that quantum uniform mixing on the hypercube is robust under the addition of perfect matchings but not much else. Our specific results include:

• The graph obtained by augmenting the hypercube with an additive matching x ↦ x ⊕ η is instantaneous uniform mixing whenever |η| is even, but with a slower mixing time. This strictly includes the result of Moore and Russell¹ on the hypercube.

• The class of Hamming graphs H(n,q) is not uniform mixing if and only if q ≥ 5. This is a tight characterization of quantum uniform mixing on Hamming graphs; previously, only the status of H(n,q) with q < 5 was known.

• The bunkbed graph whose adjacency matrix is I ⊗ Q_n + X ⊗ A_f, where A_f is a -circulant matrix defined by a Boolean function f, is not uniform mixing if the Fourier transform of f has support of size smaller than 2^n-1. This explains why the hypercube is uniform mixing and why the join of two hypercubes is not.

Our work exploits the rich spectral structure of the generalized hypercubes and relies heavily on Fourier analysis of group-circulants.

In this paper, continuous-time quantum walk on hypercube is discussed in view of Cartesian product structure. We find that the $n$-fold Cartesian power of the complete graph $K_2$ is the $n$-dimensional hypercube, which give us new ideas for the study of quantum walk on hypercube. Combining the product structure, the spectral distribution of the graph and the quantum decomposition of the adjacency matrix, the probability amplitudes of the continuous-time quantum walker’s position at time $t$ are given, and it is discussed that the probability distribution for the continuous-time case is uniform when $t=(\pi ∕4)n$. The application of this product structure greatly improves the study of quantum walk on complex graphs, which has far-reaching influence and great significance.