2015
DOI: 10.1103/physreve.92.062924
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Quantum signatures of chimera states

Abstract: Chimera states are complex spatiotemporal patterns in networks of identical oscillators, characterized by the coexistence of synchronized and desynchronized dynamics. Here we propose to extend the phenomenon of chimera states to the quantum regime, and uncover intriguing quantum signatures of these states. We calculate the quantum fluctuations about semiclassical trajectories and demonstrate that chimera states in the quantum regime can be characterized by bosonic squeezing, weighted quantum correlations, and … Show more

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Cited by 112 publications
(89 citation statements)
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“…Recent work on coupled quantum van der Pol oscillators has suggested that there may be an intimate connection between the emergence of synchronization in coupled quantum oscillators and the behavior of the mutual information [8,15,19] and it has even been suggested that mutual information could serve as an order parameter for synchronization [15].…”
Section: Mutual Information and Entanglementmentioning
confidence: 99%
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“…Recent work on coupled quantum van der Pol oscillators has suggested that there may be an intimate connection between the emergence of synchronization in coupled quantum oscillators and the behavior of the mutual information [8,15,19] and it has even been suggested that mutual information could serve as an order parameter for synchronization [15].…”
Section: Mutual Information and Entanglementmentioning
confidence: 99%
“…Studies of synchronization effects in the quantum regime have largely concentrated on the behavior of simple model systems such as van der Pol oscillators [7,9,10,12,15,17,19,21] (together with closely related models [22]), though a number of other systems including atomic ensembles [13,16] and optomechanical oscillators [5,6,12,18] have also been investigated. In this article we investigate synchronization in a very different model system consisting of two weakly coupled micromasers.…”
Section: Introductionmentioning
confidence: 99%
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“…This so-called chimera state is counter-intuitive as it appears even when the oscillators are identical, but, since its discover, this state has become a relevant subject of investigation for experimental and theoretical scientists active in different fields ranging from laser dynamics to chemical oscillators, from mechanical pendula to (computational) neuroscience. In particular chimera states have been shown to emerge in various numerical/theoretical studies [26][27][28][29][30][31][32][33][34][35] and in various experimental settings, including mechanical [36][37][38], (electro-)chemical [39][40][41] lasing systems [42,43] and BOLD fMRI signals detection during resting state activity [44], among others. Therefore chimera states are an ubiquitous phenomenon in nature much like synchronization itself and may often have been overlooked or dismissed in previous studies.…”
Section: Introductionmentioning
confidence: 99%
“…They represent an intriguing phenomenon where an ensemble of identical elements with symmetric coupling spontaneously splits into spatially separated coexisting domains of coherent (synchronized) and incoherent (desynchronized) dynamics. Since their first discovery in systems of coupled phase oscillators [2,3] they have been found in a broad range of diverse models [1,4], ranging from time-discrete maps [5] and time-continuous chaotic models [6], Stuart-Landau oscillators [7][8][9][10], globally coupled lasers [11], Van der Pol oscillators [12,13] FitzHugh-Nagumo neural systems [14,15], population dynamical models [16] to autonomous Boolean networks [17]. They have recently also been observed experimentally, e.g., in optical light modulators [18], chemical [19], mechanical [20,21], electronic [22,23], optoelectronic [24], and electrochemical [25,26] oscillator systems.…”
mentioning
confidence: 99%