Coherence-Driven Topological Transition in Quantum Metamaterials

Jha, Pankaj; Mrejen, Michael; Kim, Jeongmin; Wu, Chihhui; Wang, Yuan; Rostovtsev, Yuri V.; Zhang, Xiang

doi:10.1103/physrevlett.116.165502

Cited by 32 publications

(19 citation statements)

References 58 publications

(63 reference statements)

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“…Originating from the fundamental superposition principle of quantum mechanics, quantum coherence is a kind of important quantum resources. It plays key roles in the interference of light, the laser, superconductivity and quantum thermodynamics [1,2,3], as well as in some quantum information tasks [4,5,6,7] and biological processes [8,9,10,11]. However, the rigorous theories of quantum coherence have been proposed only recently [12].…”

Section: Introductionmentioning

confidence: 99%

Coherence generating power of unitary transformations via probabilistic average

Zhang

Chen

et al. 2018

Quantum Inf Process

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We study the ability of a quantum channel to generate quantum coherence when it applies to incoherent states. Based on probabilistic averages, we define a measure of such coherence generating power (CGP) for a generic quantum channel, based on the average coherence generated by the quantum channel acting on a uniform ensemble of incoherent states. Explicit analytical formula of the CGP for any unitary channels are presented in terms of subentropy.An upper bound for CGP of unital quantum channels has been also derived. Detailed examples are investigated. *

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Section: Introductionmentioning

confidence: 99%

Coherence generating power of unitary transformations via probabilistic average

Zhang

Chen

et al. 2018

Quantum Inf Process

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“…As a final remark, it should be noted that the large SE-enhancements in antenna nanostructures might also be of interest for creating relatively low-threshold nanolasersexcept that the optimization is, in that case, quite different. Indeed, while overall optical losses are, in a sense, beneficial in designing a good antenna (since the Q-factor of a good antenna should be of the order of unity to allow for good in-/out-coupling of radiation to the antenna), they are disadvantageous for lasers, which require small total (dissipative + radiative) losses for low-threshold operation [4,26,[40][41][42][43]. Here, a key quantity of interest is the fraction of spontaneous emission coupling to the preferred lasing mode -the, so-called, ϐ factor.…”

Section: Recent Experimental Progressmentioning

confidence: 99%

Large spontaneous-emission enhancements in metallic nanostructures: towards LEDs faster than lasers [Invited]

et al. 2016

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Recent progress in the design and realization of optical antennas enclosing fluorescent materials has demonstrated large spontaneous-emission enhancements and, simultaneously, high radiation efficiencies. We discuss here that an important objective of such work is to increase spontaneous-emission rates to such a degree that light-emitting diodes (LEDs) can possess modulation speeds exceeding those of typical semiconductor lasers, which are usually in the range ~20-50 GHz. We outline the underlying physics that enable large spontaneous-emission enhancements in metallic nanostructures, and we then discuss recent theoretical and experimentally promising results, where enhancements larger than a factor of ~300 have been reported, with radiation efficiencies exceeding 50%. We provide key comparative advantages of these structures in comparison to conventional dielectric microcavity designs, namely the fact that the enhancement of spontaneous emission can be relatively nonresonant (i.e., broadband) and that the antenna nanostructures can be spectrally and structurally compatible for integration with a wide class of emitters, including organic dyes, diamond nanocrystals and colloidal quantum dots. Finally, we point out that physical insight into the underlying effects can be gained by analyzing these metallic nanostructures in their equivalent-circuit (or nano-antenna) model, showing that all main effects (including the Purcell factor) can adequately be described in that approach.

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“…Moreover, there is a growing interest in light propagation through a nanometer-size sample of homogeneously broadened (i.e. low-temperature) atoms with a sufficiently high number density due to potential applications in the areas of efficient light transport [2], quantum information processing [3], metamaterials [4], integrated optical devices [5], and nano-optics [6]. Recently realized experiments [7][8][9][10][11] for cold dense atoms motivate theoretical investigations [12][13][14][15][16][17][18][19][20][21][22][23][24] of light propagation at the microscopic level.…”

Section: Introductionmentioning

confidence: 99%

Strongly coupled cold atoms in bilayer dense lattices

Yoo

2018

New J. Phys.

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We theoretically investigate the optical response of many cold atoms within a pair of identical planar lattices mostly in a dense regime using microscopic electrodynamics numerical simulations. We find cooperative optical properties of the double atomic lattices to a normal incidence of low-intensity radiation at particular ranges of sample parameters. The main findings are that resonance shifts, linewidths, and transmittance could be engineered by varying layer-to-layer distance, lattice constant, and parameters for incident light. We also propose a bilayer atomic lattice could be modeled as two effective superatoms. Simulation results qualitatively agree with the ones from an isotropic infinite lattice model in the ranges of external parameters for which a mean-field approximation is not valid. Hopefully, our bilayer lattice samples might be exploited for implementing an optical switch and a photonic device in quantum computing.

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Coherence-Driven Topological Transition in Quantum Metamaterials

Cited by 32 publications

References 58 publications

Coherence generating power of unitary transformations via probabilistic average

Coherence generating power of unitary transformations via probabilistic average

Large spontaneous-emission enhancements in metallic nanostructures: towards LEDs faster than lasers [Invited]

Strongly coupled cold atoms in bilayer dense lattices

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