Chiral Emission into Nanophotonic Resonators

Martín-Cano, Diego; Haakh, Harald R.; Rotenberg, Nir

doi:10.1021/acsphotonics.8b01555

Cited by 41 publications

(37 citation statements)

References 34 publications

(72 reference statements)

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“…A promising approach is to exploit chiral quantum optics to form a chiral interface that facilitates the unidirectional transfer of the spin to the guided photons. [27] To date, chiral coupling has been intensively evaluated in various nanophotonic structures including metal surfaces, [28,29] optical fibers, [30,31] semiconductor waveguides, [32][33][34][35] microresonators, [36][37][38][39][40][41][42][43] and topological nanostructures. [44,45] Particularly, the tightly confined light field carries transverse spin angular momentum; thus, a link between the spin and propagation direction of light can be introduced.…”

Section: Introductionmentioning

confidence: 99%

“…To date, chiral coupling has been intensively evaluated in various nanophotonic structures including metal surfaces, [ 28,29 ] optical fibers, [ 30,31 ] semiconductor waveguides, [ 32–35 ] microresonators, [ 36–43 ] and topological nanostructures. [ 44,45 ] Particularly, the tightly confined light field carries transverse spin angular momentum; thus, a link between the spin and propagation direction of light can be introduced.…”

Section: Introductionmentioning

confidence: 99%

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Chiral Photonic Circuits for Deterministic Spin Transfer

Xiao

Xie

et al. 2021

Laser & Photonics Reviews

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Chiral quantum optics has attracted considerable interest in the field of quantum information science. Exploiting the spin-polarization properties of quantum emitters and engineering rational photonic nanostructures has made it possible to transform information from spin to path encoding. Here, compact chiral photonic circuits with deterministic circularly polarized chiral routing and beamsplitting are demonstrated using two laterally adjacent waveguides coupled with quantum dots. Chiral routing arises from the electromagnetic field chirality in waveguide, and beamsplitting is obtained via the evanescent field coupling. The spin-and position-dependent directional spontaneous emission are achieved by spatially selective micro-photoluminescence measurements, with a chiral contrast of up to 0.84 in the chiral photonic circuits. This makes a significant advancement for broadening the application scenarios of chiral quantum optics and developing scalable quantum photonic networks.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Chiral Photonic Circuits for Deterministic Spin Transfer

Xiao

Xie

et al. 2021

Laser & Photonics Reviews

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“…Novel phenomena stemming from asymmetric coupling have been studied theoretically in a range of systems, including spin networks [27], cavity-based photonic devices [28,29], quantum emitters coupled to plasmonic waveguides [30,31], nanophotonic ring resonators [32,33], synthetic phonons [34], and Janus dipoles [35]. Recently, it was shown that chiral coupling at the nanoscale naturally arises in the system of two circularly polarized quantum emitters held above a metal surface, where the surface plasmons mediating the emitteremitter interactions can be controlled in a manifestation of reservoir engineering [36].…”

Section: Introductionmentioning

confidence: 99%

Asymmetric coupling between two quantum emitters

et al. 2020

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We study a prototypical model of two coupled two-level systems, where the competition between coherent and dissipative coupling gives rise to a rich phenomenology. In particular, we analyze the case of asymmetric coupling, as well as the limiting case of chiral (or one-way) coupling. We investigate various quantum optical properties of the system, including its steady-state populations, power spectrum, and second-order correlation functions, and outline the characteristic features which emerge in each quantity as one sweeps through the nontrivial landscape of effective complex couplings. Most importantly, we reveal instances of population trapping, unexpected spectral features, and strong emission correlations.

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“…A number of associated experiments have been implemented. Besides, this chiral lightmatter interaction between photonic nanostructure and quantum emitter has also been realized in other structures, such as nanobeam waveguides [34,45], optical resonators [46,47], and metamaterials [48]. Here, more details about systematic theoretical research and applications for chiral quantum interface in conventional nanostructures have been reviewed in Ref.…”

Section: Progress In Chiral Quantum Interface and Topological Photonicsmentioning

confidence: 99%

Recent Progress in Chiral Topological Quantum Interface

Jiang

Qiao

et al. 2022

Front. Phys.

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Chiral quantum optics and Topological photonics are both emerging field of research, which have attracted great attention in recent years. Chiral quantum optics provides a new approach to achieve full quantum control of light-matter interaction in a novel manner, which has potential possibility for the implementation of complex quantum information networks. Meanwhile, topological photonics provides a novel route for designing and realizing optical device with unprecedented functionality, such as robust light propagation, the immunity to various structural imperfection, back-scattering suppression as well as unidirectional transmission. The application of topological photonics in chiral quantum optics will promote the whole performance of integrated quantum device with topological protection. In this review, we summarize the progress of chiral quantum optics and topological photonics firstly. Then, we mainly focus on the research of topological chiral edge states based on photonic quantum spin-Hall effect and photonic quantum valley-Hall effect. Furthermore, we introduce the recent work of chiral topological quantum interface formed by embedding quantum dot into the interface between two topologically distinct photonic crystal structures. At last, we give short outlook on the future development direction and prospect for application of topological chiral quantum interface.

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Chiral Emission into Nanophotonic Resonators

Cited by 41 publications

References 34 publications

Chiral Photonic Circuits for Deterministic Spin Transfer

Chiral Photonic Circuits for Deterministic Spin Transfer

Asymmetric coupling between two quantum emitters

Recent Progress in Chiral Topological Quantum Interface

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