Antiferromagnetic long-range order in dissipative Rydberg lattices

Hoening, Michael; Abdussalam, Wildan; Fleischhauer, Michael; Pohl, Thomas

doi:10.1103/physreva.90.021603

Cited by 72 publications

(113 citation statements)

References 70 publications

Supporting

Mentioning

111

Contrasting

Order By: Relevance

“…However, it can be difficult [8] to establish unambiguously the relation between microscopic processes and emerging kinetic constraints, or between idealized models with explicit kinetic constraints and actual physical systems. In this Rapid Communication we establish such a direct connection by reporting the experimental observation of correlated manybody excitation dynamics in a strongly interacting Rydberg gas [9][10][11][12] whose origin lies in explicit kinetic constraints that can be theoretically derived from the quantum-mechanical equations of motion of the system. We explore two kinds of kinetic constraints which lead to the suppression or the facilitation of atomic excitations in the vicinity of atoms excited to Rydberg states.…”

mentioning

confidence: 94%

See 1 more Smart Citation

Experimental observation of controllable kinetic constraints in a cold atomic gas

et al. 2016

View full text Add to dashboard Cite

Many-body systems relaxing to equilibrium can exhibit complex dynamics even if their steady state is trivial. In situations where relaxation requires highly constrained local particle rearrangements, such as in glassy systems, this dynamics can be difficult to analyze from first principles. The essential physical ingredients, however, can be captured by idealized lattice models with so-called kinetic constraints. While so far constrained dynamics has been considered mostly as an effective and idealized theoretical description of complex relaxation, here we experimentally realize a many-body system exhibiting manifest kinetic constraints and measure its dynamical properties. In the cold Rydberg gas used in our experiments, the nature of the kinetic constraints can be tailored through the detuning of the excitation lasers from resonance. The system undergoes a dynamics which is characterized by pronounced spatial correlations or anticorrelations, depending on the detuning. Our results confirm recent theoretical predictions, and highlight the analogy between the dynamics of interacting Rydberg gases and that of certain soft-matter systems. DOI: 10.1103/PhysRevA.93.040701 Complex collective relaxation in many-body systems is often accompanied by a dramatic slowdown of diffusion processes and the emergence of nonergodic and glassy phases [1][2][3][4]. At low temperatures or high densities their evolution is often dominated by steric hindrances affecting particle motion. Local rearrangements are highly constrained, giving rise to collective-and often slow-relaxation. These features can be seen to be the consequence of effective kinetic constraints in the dynamics [5]. A kinetic constraint is a condition on the rate for a local transition dependent on the local environment: The transition and its reverse-irrespective of whether they are energetically favorable or unfavorable-can only occur if the constraint is satisfied. Kinetic constraints [6] can severely restrict relaxation in situations where local particle arrangements make satisfying them unlikely, which is typical of fluid systems with excluded volume interactions such as dense colloids or supercooled liquids [1][2][3][4]. When a constraint is satisfied, however, the transition is allowed and a local rearrangement is "facilitated" [5,6]. Kinetic constraints naturally give rise [7] to collective and spatially heterogeneous relaxation, and are used to describe situations where the correlation properties of the dynamics go beyond those of the static stationary state, a salient feature of glassy systems [4].Steric hindrances and dynamic facilitation are argued to play a central role in the behavior of glass formers [5]. However, it can be difficult [8] to establish unambiguously the relation between microscopic processes and emerging kinetic constraints, or between idealized models with explicit kinetic constraints and actual physical systems. In this Rapid Communication we establish such a direct connection by reporting the experimental observation of correlated...

show abstract

mentioning

confidence: 94%

“…In this strong dissipation limit the evolution of the many-body system is restricted to the subspace of classical spin configurations by virtue of the quantum Zeno effect [15]. The dynamics can be written as a classical rate equation with rates for excitation and deexcitation [9,11],…”

mentioning

confidence: 99%

Experimental observation of controllable kinetic constraints in a cold atomic gas

et al. 2016

View full text Add to dashboard Cite

show abstract

“…In the latter context, a careful engineering of the coupling between the system and the environment can stabilize interesting many-body phases in the steady state 21,22 . The phase-diagram of such lattice systems has been predicted to be incredibly rich [23][24][25][26][27][28][29][30] and can display spontaneous ordering associated with the breaking of a discrete [31][32][33] or continuous symmetry 34,35 possessed by the model. Recently, the critical behavior emerging at the onset of phase transitions started to be investigated by means of different analytical and numerical approaches [36][37][38][39] .…”

Section: Introductionmentioning

confidence: 99%

Linked cluster expansions for open quantum systems on a lattice

et al. 2018

View full text Add to dashboard Cite

We propose a generalization of the linked-cluster expansions to study driven-dissipative quantum lattice models, directly accessing the thermodynamic limit of the system. Our method leads to the evaluation of the desired extensive property onto small connected clusters of a given size and topology. We first test this approach on the isotropic spin-1/2 Hamiltonian in two dimensions, where each spin is coupled to an independent environment that induces incoherent spin flips. Then we apply it to the study of an anisotropic model displaying a dissipative phase transition from a magnetically ordered to a disordered phase. By means of a Padé analysis on the series expansions for the average magnetization, we provide a viable route to locate the phase transition and to extrapolate the critical exponent for the magnetic susceptibility.

show abstract

“…Such systems rely on the Rydberg atom blockade effect [11][12][13], which is a density limitation of Rydberg atomic population due to the strong interaction between the atoms. However, these same interactions may lead to coherenceloss on atomic samples [14]. Such interaction can present either advantages or disadvantages in atomic systems, therefore they need to be well understood.…”

mentioning

confidence: 99%