The PT-symmetry-breaking transition in a chain of trapped interacting ions
Abstract
Trapped ions are an ideal platform to implement quantum simulation. Previously the parity-time reversal (PT) symmetry-breaking transition in the paradigmatic non-Hermitian Hamiltonian hPT=Jσx-iσz has been observed in a single ion experiment in a passive way. In this work, we propose to study the interaction effects on the PT-symmetry-breaking transition in a chain of N trapped interacting ions. We consider an effective Ising interaction HIsing-xint =Σj<kUjkσxjσxk between the ions on top of hPT. We find that sufficiently strong interaction strength can enhance the PT-symmetric phase for even N while the phase is suppressed in all the other cases. In particular, the suppression can be so strong that even infinitesimal dissipation, quantified by , can turn the system into the PT-symmetry-breaking phase. In addition, we assess the convolved effects due to the coupling and the spin phase shifts. Our findings can be readily tested in ion chain experiments.
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