81 research outputs found
Exact results on the quench dynamics of the entanglement entropy in the toric code
We study quantum quenches in the two-dimensional Kitaev toric code model and
compute exactly the time-dependent entanglement entropy of the non-equilibrium
wave-function evolving from a paramagnetic initial state with the toric code
Hamiltonian. We find that the area law survives at all times. Adding disorder
to the toric code couplings makes the entanglement entropy per unit boundary
length saturate to disorder-independent values at long times and in the
thermodynamic limit. There are order-one corrections to the area law from the
corners in the subsystem boundary but the topological entropy remains zero at
all times. We argue that breaking the integrability with a small magnetic field
could change the area law to a volume scaling as expected of thermalized states
but is not sufficient for forming topological entanglement due to the presence
of an excess energy and a finite density of defects.Comment: 14 pages, 7 figures, published versio
Optimal control for unitary preparation of many-body states: application to Luttinger liquids
Many-body ground states can be prepared via unitary evolution in cold atomic
systems. Given the initial state and a fixed time for the evolution, how close
can we get to a desired ground state if we can tune the Hamiltonian in time?
Here we study this optimal control problem focusing on Luttinger liquids with
tunable interactions. We show that the optimal protocol can be obtained by
simulated annealing. We find that the optimal interaction strength of the
Luttinger liquid can have a nonmonotonic time dependence. Moreover, the system
exhibits a marked transition when the ratio of the preparation time to
the system size exceeds a critical value. In this regime, the optimal protocols
can prepare the states with almost perfect accuracy. The optimal protocols are
robust against dynamical noise.Comment: 4 pages, 4 figures, extended results on robustness, to appear in PR
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