L. I. R. Gil scite author profile

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Non-equilibrium physics of Rydberg lattices in the presence of noise and dissipative processes

Abdussalam

Gil

2016

Eur. Phys. J. Spec. Top.

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Abstract. We study the non-equilibrium dynamics of driven spin lattices in the presence of decoherence caused by either laser phase noise or strong decay. In the first case, we discriminate between correlated and uncorrelated noise and explore their effect on the mean density of Rydberg states and the full counting statistics (FCS). We find that while the mean density is almost identical in both cases, the FCS differ considerably. The main method employed is the Langevin equation (LE) but for the sake of efficiency in certain regimes, we use a Markovian master equation and Monte Carlo rate equations, respectively. In the second case, we consider dissipative systems with more general powerlaw interactions. We determine the phase diagram in the steady state and analyse its generation dynamics using Monte Carlo rate equations. In contrast to nearest-neighbour models, there is no transition to long-range-ordered phases for realistic interactions and resonant driving. Yet, for finite laser detunings, we show that Rydberg lattices can undergo a dissipative phase transition to a long-range-ordered antiferromagnetic (AF) phase. We identify the advantages of Monte Carlo rate equations over mean field (MF) predictions.

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Rydberg spin-squeezing for a strontium optical lattice clock

Bridge

Boddy

Sadler

et al. 2014

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L. I. R. Gil

Spin Squeezing in a Rydberg Lattice Clock

Non-equilibrium physics of Rydberg lattices in the presence of noise and dissipative processes

Rydberg spin-squeezing for a strontium optical lattice clock

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