Continuous-time quantum walks over connected graphs, amplitudes and invariants

Abstract

We examine the time dependent amplitude φj( t) at each vertex j of a continuous-time quantum walk on the cycle Cn. In many cases the Lissajous curve of the real vs. imaginary parts of each φj( t) reveals interesting shapes of the space of time-accessible amplitudes. We find two invariants of continuous-time quantum walks. First, considering the rate at which each amplitude evolves in time we find the quantity T = Σj=0n-1 d φj( t)d t2 is time invariant. The value of T for any initial state can be minimized with respect to a global phase factor ei θ t to some value Tmin. An operator for Tmin is defined. For any simply connected graph g the highest possible value of Tmin with respect to the initial state is found to be Tminmax=( λmax2)2 where λmax is the maximum eigenvalue in the Laplace spectrum of g. A second invariant is found in the time-dependent probability distribution Pj(t) = φj(t)2 of any initial state satisfying Tminmax, with these conditions Σj=0n-1(Pjmax - Pjmin)2 = 4n for all simply connected graphs of n vertices.