Min-Soo Hwang scite author profile

Topological photonics in strongly coupled light-matter systems offer the possibility for fabricating tunable optical devices that are robust against disorder and defects. Topological polaritons, i.e., hybrid exciton-photon quasiparticles, have been proposed to demonstrate scatter-free chiral propagation, but their experimental realization to date have been at deep cryogenic temperatures and under strong magnetic fields. We demonstrate helical topological polaritons up to 200 K without external magnetic field in monolayer WS2 excitons coupled to a non-trivial photonic crystal protected by pseudo time-reversal symmetry. The helical nature of the topological polaritons is verified where polaritons with opposite helicities are transported to opposite directions. Topological helical polaritons provide a platform for developing robust and tunable polaritonic spintronic devices for classical and quantum information processing applications.

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Ultralow-threshold laser using super-bound states in the continuum

Hwang

et al. 2021

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Wavelength-scale lasers provide promising applications through low power consumption requiring for optical cavities with increased quality factors. Cavity radiative losses can be suppressed strongly in the regime of optical bound states in the continuum; however, a finite size of the resonator limits the performance of bound states in the continuum as cavity modes for active nanophotonic devices. Here, we employ the concept of a supercavity mode created by merging symmetry-protected and accidental bound states in the continuum in the momentum space, and realize an efficient laser based on a finite-size cavity with a small footprint. We trace the evolution of lasing properties before and after the merging point by varying the lattice spacing, and we reveal this laser demonstrates the significantly reduced threshold, substantially increased quality factor, and shrunken far-field images. Our results provide a route for nanolasers with reduced out-of-plane losses in finite-size active nanodevices and improved lasing characteristics.

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Z₂ Photonic Topological Insulators in the Visible Wavelength Range for Robust Nanoscale Photonics

Liu

Hwang

et al. 2020

Nano Lett.

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Topological photonics provides an ideal platform for demonstrating novel band topology concepts, which are also promising for robust waveguiding, communication and computation applications. However, many challenges such as extremely large device footprint and functionality at short wavelengths remain to be solved which are required to make practical and useful devices that can also couple to electronic excitations in many important organic and inorganic semiconductors. In this letter, we report an experimental realization of Z2 photonic topological insulators with their topological edge state energies spanning across the visible wavelength range including in the sub-500 nm regime. The photonic structures are based on deformed hexagonal lattices with preserved six-fold rotational symmetry patterned on suspended SiNx membranes. The experimentally measured energy-momentum dispersion of the topological lattices directly show topological band inversion by the swapping of the brightness of the bulk energy bands, and also 2 the helical edge states when the measurement is taken near the topological interface. The robust topological transport of the helical edge modes in real space is demonstrated by successfully guiding circularly polarized light beams unidirectionally through sharp kinks without major signal loss. This work paves the way for small footprint photonic topological devices working in the short wavelength range that can also be utilized to couple to excitons for unconventional light-matter interactions at the nanoscale. Keywords: photonic topological insulator, photonic crystal, visible-wavelength topological photonicsArising from the demonstrated generality of band topology concepts borrowed from solidstate electronic band structures, photonic topological insulators (PTIs) exhibit topologically protected edge states that lead to unique optical transport properties such as immunity to defects and lossless propagation through sharp turns, hence providing a promising platform to build robust photonic waveguides, communication lines and circuits. 1-3 Furthermore, given the flexibility of system design and fabrication with various optical materials, PTIs serve as testbeds in demonstrating concepts that are otherwise difficult to achieve in condensed matter systems, such as Floquet topological insulators 4-7 , higher order PTIs 8-14 , and PT-symmetric topological structures [15][16][17] . PTIs have now been demonstrated in various geometries, including gratings and arrays in one dimension 18-23 , photonic and plasmonic lattices and fiber arrays in two-dimensions 24-39 , as well as three-dimensional PTIs 40-42 , and with different mechanisms such as SSH insulators 19-23 , Chern 24-27 and valley Chern insulators [28][29][30][31][32] , and 2D and 3D Z2 topological insulators [34][35][36][37][38][39] . PTIs

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Observation and Active Control of a Collective Polariton Mode and Polaritonic Band Gap in Few-Layer WS₂ Strongly Coupled with Plasmonic Lattices

et al. 2019

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Two-dimensional semiconductors host excitons with very large oscillator strengthsand binding energies due to significantly reduced carrier screening. Two-dimensional semiconductors integrated with optical cavities are emerging as a promising platform for studying strong light-matter interactions as a route to explore a variety of exotic many-body effects. Here, in few-layered WS2 coupled with plasmonic nanoparticle lattices, we observe the formation of a collective polaritonic mode near the exciton energy and the formation of

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Coherent Interactions in One-Dimensional Topological Photonic Systems and Their Applications in All-Optical Logic Operation

Wang

Liu

et al. 2020

Nano Lett.

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Topological photonics has become an active subfield of photonics analogous to the electronic counterpart, and the bulk-edge correspondence leads to robust topologically protected interfacial states. However, a single-topological interface mode with fixed energy cannot be easily manipulated, hindering its applications in optical devices. Here, we study coupled-waveguide arrays mapped to a one-dimensional Su–Schrieffer–Heeger system with two coupled topological interfaces. This configuration greatly increases device versatility and tunability while keeping the confinement of coupled-interface modes inherited from the topological properties nearly intact. Theoretically predicted oscillations between coupled interfaces is experimentally observed. The spatial and energetic isolation of the coupled interface states from the bulk modes is experimentally observed and theoretically confirmed by calculating the degree of localization of the eigenstates, which is found to be comparable to a single-interface state. Finally, a proof-of-principle, all-optical logic circuit is fabricated based on coupled interfaces, demonstrating its potential in assembling on-chip topological optical devices.

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Min-Soo Hwang

Generation of helical topological exciton-polaritons

Ultralow-threshold laser using super-bound states in the continuum

Z₂ Photonic Topological Insulators in the Visible Wavelength Range for Robust Nanoscale Photonics

Observation and Active Control of a Collective Polariton Mode and Polaritonic Band Gap in Few-Layer WS₂ Strongly Coupled with Plasmonic Lattices

Coherent Interactions in One-Dimensional Topological Photonic Systems and Their Applications in All-Optical Logic Operation

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Min-Soo Hwang

Generation of helical topological exciton-polaritons

Ultralow-threshold laser using super-bound states in the continuum

Z2 Photonic Topological Insulators in the Visible Wavelength Range for Robust Nanoscale Photonics

Observation and Active Control of a Collective Polariton Mode and Polaritonic Band Gap in Few-Layer WS2 Strongly Coupled with Plasmonic Lattices

Coherent Interactions in One-Dimensional Topological Photonic Systems and Their Applications in All-Optical Logic Operation

Contact Info

Product

Resources

About

Z₂ Photonic Topological Insulators in the Visible Wavelength Range for Robust Nanoscale Photonics

Observation and Active Control of a Collective Polariton Mode and Polaritonic Band Gap in Few-Layer WS₂ Strongly Coupled with Plasmonic Lattices