We study the time evolution of the entanglement entropy of a one-dimensional
nonintegrable spin chain, starting from random nonentangled initial pure
states. We use exact diagonalization of a nonintegrable quantum Ising chain
with transverse and longitudinal fields to obtain the exact quantum dynamics.
We show that the entanglement entropy increases linearly with time before
finite-size saturation begins, demonstrating a ballistic spreading of the
entanglement, while the energy transport in the same system is diffusive. Thus
we explicitly demonstrate that the spreading of entanglement is much faster
than the energy diffusion in this nonintegrable system.Comment: 7 pages, 7 figures. Published version. Supplementary material adde
