Strong Coupling of Exciton and High‐<i>Q</i> Mode in All‐Perovskite Metasurfaces

Al-Ani, Ibrahim; As’ham, Khalil; Huang, Lujun; Miroshnichenko, Andrey E.; Lei, Wen; Hattori, Haroldo T.

doi:10.1002/adom.202101120

Cited by 52 publications

(20 citation statements)

References 53 publications

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“…85 Theoretical studies on polaritonic BICs in the perovskite platform were also reported recently. 86,87 In conclusion, we demonstrated topological polarization singularities in polariton emission. The polarization vortices (in circular patterns) and CP eigenstates (in symmetry-broken patterns) were measured by the Stokes parameter measurements of PL in momentum space.…”

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confidence: 50%

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Topological Control of 2D Perovskite Emission in the Strong Coupling Regime

Kim

Woo

et al. 2021

Nano Lett.

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Momentum space topology can be exploited to manipulate radiation in real space. Here we demonstrate topological control of 2D perovskite emission in the strong coupling regime via polaritonic bound states in the continuum (BICs). Topological polarization singularities (polarization vortices and circularly polarized eigenstates) are observed at room temperature by measuring the Stokes parameters of photoluminescence in momentum space. Particularly, in symmetry-broken structures, a very large degree of circular polarization (DCP) of ∼0.835 is achieved in the perovskite emission, which is the largest in perovskite materials to our knowledge. In the strong coupling regime, lower polariton modes shift to the low-loss spectral region, resulting in strong emission enhancement and large DCP. Our reciprocity analysis reveals that DCP is limited by material absorption at the emission wavelength. Polaritonic BICs based on 2D perovskite materials combine unique topological features with exceptional material properties and may become a promising platform for active nanophotonic devices.

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confidence: 50%

“…The Bose–Einstein condensation was demonstrated at low temperature using polariton BICs, and a polarization vortex in the perovskite metasurface was observed at room temperature . Theoretical studies on polaritonic BICs in the perovskite platform were also reported recently. , …”

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confidence: 90%

Topological Control of 2D Perovskite Emission in the Strong Coupling Regime

Kim

Woo

et al. 2021

Nano Lett.

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“…While most of the milestones of polaritonic physics have been achieved with excitonic materials operating at cryogenic temperatures (≈10 K), recent progress in materials science has promoted many polaritonic demonstrations at room temperature with a wide variety of high bandgap semiconductors, ranging from GaN, [24,25] ZnO, [26] to organic semiconductors, [27,28] and transition metal dichalcogenide monolayers, [29,30] as well as perovskite materials. [31][32][33][34][35][36][37][38][39][40][41] Very recently, the strong coupling regime between photonic BICs and excitonic resonances has been theoretically suggested, [42][43][44][45] with two experimental demonstrations. [46,47] The result of such a coupling is the formation of polariton-BICs (pol-BICs): hybrid excitations that are completely decoupled from the radiative continuum.…”

Section: Introductionmentioning

confidence: 99%

“…[38] Most recently, it has been theoretically suggested that perovskite metasurfaces can be harnessed to engineer the imaginary part (i.e., losses) of the polaritonic energy-momentum dispersion at room temperature via BIC and exceptional point concepts. [43,45] On the other hand, purely photonic BICs in perovskite-based resonant metasurface have been reported to make ultra-fast switches [7] and tunable microlasers. [49] In this work, we experimentally demonstrate the formation of pol-BICs in an excitonic metasurface made from hybrid 2D perovskites.…”

Section: Introductionmentioning

confidence: 99%

Realization of Polaritonic Topological Charge at Room Temperature Using Polariton Bound States in the Continuum from Perovskite Metasurface

Dang

Zanotti

Drouard

et al. 2022

Advanced Optical Materials

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mechanical effect, [1] the origin of BICs is nowadays fully unraveled as a particular solution of wave equations, which has led to their exploitation in other fields where it is straightforwardly attributed to destructive interference mechanisms or symmetry mismatches. [2] The most active playground of BIC physics is in contemporary Photonics [3] since most of optoelectronic devices rely on resonances and their coupling mechanisms with environment. Indeed, the trapping of light through photonic BICs is a salient feature to enhance different light-matter interaction mechanisms, leading to various applications in microlasers, [4][5][6][7][8] sensors, [9] optical switches, [7] and nonlinear optics. [10][11][12][13] Moreover, on the fundamental side, photonic BICs in periodic lattices are pinned to singularities of farfield polarization vortex and can be considered as topological charges of nonHermitian systems. [14][15][16][17] This topological nature, together with modern technological feasibility to tailor photonic materials, makes photonic BICs a fruitful platform to engineer polarization singularities of open photonic systems. [5,[18][19][20] Another prominent area of investigation in modern Optics is represented by exciton-polaritons, elementary excitations arising from the strong coupling regime between confined light and semiconductor excitons. [21] As hybridized eigenmodes, these bosonic quasiparticles inherit original features of both Exciton-polaritons are mixed light-matter excitations resulting from the strong coupling regime between an active excitonic material and photonic resonances. Harnessing these hybrid excitations provides a rich playground to explore fascinating fundamental features, as out-of-equilibrium Bose-Einstein condensation and quantum fluids of light, plus novel mechanisms to be exploited in optoelectronic devices. The formation of exciton-polaritons arising from the mixing between hybrid inorganic-organic perovskite excitons and an optical bound state in a continuum (BIC) of a subwavelength-scale metasurface, are experimentally investigated at room temperature. These polaritonic eigenmodes, hereby called polariton BICs (pol-BICs) are revealed in reflectivity, resonant scattering, and photoluminescence measurements. Although pol-BICs only exhibit a finite quality factor bounded by the nonradiative losses of the excitonic component, they fully inherit BIC peculiar features: a full uncoupling from the radiative continuum in the vertical direction, which is associated to a locally vanishing farfield radiation in momentum space. Most importantly, the experimental results confirm that the topological nature of the photonic BIC is perfectly transferred to the pol-BIC. This is evidenced by the observation of a polarization vortex in the farfield of polaritonic emission. The results pave the way to engineer BIC physics of interacting bosons and novel room temperature polaritonic devices.

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“…1,21 Later on, multilayer microcavity schemes with some large binding energy materials were used to obtain hybrid exciton-polariton, [22][23][24][25][26][27] but these were limited by the difficulty of fabrication. Very recently, thanks to the incorporation of lead halide perovskites [28][29][30][31][32] and two-dimensional materials, [33][34][35][36][37][38][39] the disadvantages faced previously have been swept away, which paves the way for the realization of exciton-polariton through strong coupling with specially designed photonic structures at room temperature.…”

Section: Introductionmentioning

confidence: 99%

Strong coupling of excitons in patterned few-layer WS₂ with guided mode and bound state in the continuum

Qing

2022

Phys. Chem. Chem. Phys.

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Strong Coupling of Exciton and High‐Q Mode in All‐Perovskite Metasurfaces

Cited by 52 publications

References 53 publications

Topological Control of 2D Perovskite Emission in the Strong Coupling Regime

Topological Control of 2D Perovskite Emission in the Strong Coupling Regime

Realization of Polaritonic Topological Charge at Room Temperature Using Polariton Bound States in the Continuum from Perovskite Metasurface

Strong coupling of excitons in patterned few-layer WS₂ with guided mode and bound state in the continuum

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Strong Coupling of Exciton and High‐Q Mode in All‐Perovskite Metasurfaces

Cited by 52 publications

References 53 publications

Topological Control of 2D Perovskite Emission in the Strong Coupling Regime

Topological Control of 2D Perovskite Emission in the Strong Coupling Regime

Realization of Polaritonic Topological Charge at Room Temperature Using Polariton Bound States in the Continuum from Perovskite Metasurface

Strong coupling of excitons in patterned few-layer WS2 with guided mode and bound state in the continuum

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Strong coupling of excitons in patterned few-layer WS₂ with guided mode and bound state in the continuum