Robustness of Dicke subradiance against thermal decoherence

Weiss, P.B.; Cipris, A.; Araújo, Michelle O.; Kaiser, Robin; Guerin, William

doi:10.1103/physreva.100.033833

Cited by 34 publications

(20 citation statements)

References 36 publications

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“…Note that the simple model developed in this work may shed light on the recently demonstrated robustness of the subradiant state decay time for an ensemble of cold atoms with the increasing of temperature [51]. In this regard, the toy-model that describes long-lived entanglement may be useful for qualitative analyses.…”

Section: Discussionmentioning

confidence: 89%

Dephasing-assisted entanglement in a system of strongly coupled qubits

Vovcenko,

Shishkov,

Andrianov

2020

Preprint

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Creation of entangled states of quantum systems with low decoherence rates is a cornerstone in practical implementation of quantum computations. Processes of separate dephasing in each qubit in experimentally feasible systems is commonly accepted to destroy entanglement. In this work, we consider a system of two strongly coupled qubits that interact with dephasing reservoirs. We demonstrate that interaction with dephasing reservoirs can contribute to the formation of a long-lived mixed entangled state with nonzero concurrence. The weight of the subradiant state in this mixed state tends toward unity if the dephasing rate is much larger than the radiative rate and less than the coupling constant between qubits. The lifetime of this state is proportional to the exponent of the ratio of the coupling constant to environmental temperature and can be, by orders of magnitude, larger than the system's characteristic dephasing and dissipation times. Therefore, high dephasing, along with strong coupling, contributes to the creation of an entangled state with a long lifetime. This result paves the way for creation of long-lived entangled states. I. INTRODUCTIONEntangled states of two or more qubits are the building blocks of quantum computers and elements of quantum communication systems [1]. The concept of entanglement was first proposed for the pure state, which can be described in terms of wave function [2][3][4][5]. However, all real systems inevitably interact with the environment. This leads to a state of the system ceases to be pure and becomes a mixed state, which can be described only in terms of a density matrix. The concept of entanglement can be extended to mixed states, as well [6]. The system-environment interaction leads to processes of dissipation and dephasing or decoherence. The first leads to change in both energy and coherence, while the second process does not change the energy and results in destruction of coherence. This manifests as dissipation of only the non-diagonal density matrix elements. In real systems, the dephasing rate is up to five orders of magnitude higher than the dissipation rate [7,8] and it is responsible for the fast destruction of the entanglement.One basic element for entanglement creation is an ensemble of two two-level systems (TLSs) interacting with the environment and, possibly, each other [9][10][11][12][13]. The problem of entanglement creation in such a system has been investigated in many works [14][15][16][17][18][19][20], and several opportunities to create and conserve entanglement exist. One can enhance the interaction between TLSs in such a way that the ground state of the system becomes entangled [17,20] or use coherent external drive to move the system into the entangled state [21,22]. The use of common reservoirs for two qubits is another way to create entanglement [14,16,18,23].Free space modes of electromagnetic field are an example of common reservoirs for dipole moments of atoms or molecules. When they occupy subwavelength volume, an entangled subradiant state,...

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Section: Discussionmentioning

confidence: 89%

Dephasing-assisted entanglement in a system of strongly coupled qubits

Vovcenko,

Shishkov,

Andrianov

2020

Preprint

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“…We find that the slope (n lin C − n C )/(n C I in ) has a pronounced dependence on which collective mode is driven, with a smaller υ α resulting in a larger slope in all but one case. 2 The drive mode-matched to the υ α = 0.96γ mode, for example, results in appreciable deviation between n C and n lin C at intensities I in 0.02I s , whereas a drive modematched to the most superradiant mode (υ α = 1.41γ) shows similar deviation at thrice this intensity. A more extreme case occurs when the lattice spacing is increased to a = 0.6λ.…”

Section: A Coherent Scatteringmentioning

confidence: 92%

“…can scatter coherently multiple times between the resonators, resulting in strong light-mediated, long-range interactions. This provides a highly controllable system to explore classical and quantum many-body physics, which has been shown to boast subradiance [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15] and other collective phenomena in trapped atomic ensembles and in resonator arrays [38][39][40][41], with potential applications to quantum information processing [42][43][44], the studies of nontrival topological phases [45][46][47], and atomic clocks [48][49][50][51].…”

Section: Introductionmentioning

confidence: 99%

Optical response of atom chains beyond the limit of low light intensity: The validity of the linear classical oscillator model

Williamson,

Ruostekoski

2020

Preprint

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“…[57][58] The cooperative scattering of light 18 leads to many-body effects with a rich physics. Since Dicke's work on coherence in the spontaneous emission superradiance 9,15,[59][60] , an enhancement in the field emission with collective decay rate larger than the single atom one Γ N > Γ, and its counterpart subradiance 10,[61][62][63] Γ N < Γ have been studied both from the theoretical 12, 64-65 and experimental 10, 66-67 side. However, most of the work in the literature were performed in the linear optics limit, with at most one excitation in the system and, in particular for the radiated far-field intensity, its decay dynamics is well understood in the switch-off protocol, thus there is no Rabi oscillations after the laser is turned off.…”

Section: Application To the Dynamics Of The Radiated Intensitymentioning

confidence: 99%

“…24 we compare the experimental signal with MF and CD simulations for higher saturation parameter s. From the experimental side, the same setup described in section 4.1.1.1 is used with some upgrades. [61][62] The experiment is still in development for high saturation parameter and some issues, for example, higher temperature in the system and higher laser switch-on time (17ns), are being addressed to study this regime with a better control of the different parameters. Note that, increasing the saturation parameter ( Fig.…”

Section: Beyond Linear Opticsmentioning

confidence: 99%

Quantum collective effects in a dilute cloud of two-level atoms interacting with a classical light

Santo¹

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Robustness of Dicke subradiance against thermal decoherence

Cited by 34 publications

References 36 publications

Dephasing-assisted entanglement in a system of strongly coupled qubits

Dephasing-assisted entanglement in a system of strongly coupled qubits

Optical response of atom chains beyond the limit of low light intensity: The validity of the linear classical oscillator model

Quantum collective effects in a dilute cloud of two-level atoms interacting with a classical light

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