Jiaqi Hu scite author profile

The unique optical properties of transition metal dichalcogenide (TMD) monolayers have attracted significant attention for both photonics applications and fundamental studies of low-dimensional systems. TMD monolayers of high optical quality, however, have been limited to micron-sized flakes produced by low-throughput and labour-intensive processes, whereas large-area films are often affected by surface defects and large inhomogeneity. Here we report a rapid and reliable method to synthesize macroscopic-scale TMD monolayers of uniform, high optical quality. Using 1-dodecanol encapsulation combined with gold-tape-assisted exfoliation, we obtain monolayers with lateral size > 1 mm, exhibiting exciton energy, linewidth, and quantum yield uniform over the whole area and close to those of high-quality micron-sized flakes. We tentatively associate the role of the two molecular encapsulating layers as isolating the TMD from the substrate and passivating the chalcogen vacancies, respectively. We demonstrate the utility of our encapsulated monolayers by scalable integration with an array of photonic crystal cavities, creating polariton arrays with enhanced light-matter coupling strength. This work provides a pathway to achieving high-quality two-dimensional materials over large areas, enabling research and technology development beyond individual micron-sized devices.

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Direct Generation of Radially Polarized Vector Vortex Beam with an Exciton-Polariton Laser

Kim

Schneider

et al. 2020

Phys. Rev. Applied

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Vector vortex beams are a class of optical beams with singularities in their space-variant polarization. Vector vortex beam lasers have applications in many areas including imaging and communication, where vertical cavity lasers emitting Gaussian beams have been most widely used so far. Generation of vector vortex beams from vertical cavity lasers has required external control or modulation. Here, by utilizing a polarization-selective sub-wavelength grating as one of the reflectors in a vertical semiconductor microcavity, we design the spin textures of the polariton mode and demonstrate polariton lasing in a single-mode, radially polarized vector vortex beam. Polarization and phase distributions of the emission are characterized by polarization-resolved imaging and interferometry. This way of vector vortex laser beam generation allows ultra-low threshold power, stable single-mode operation, scalability and on-chip integration, all of which are important for applications in imaging and communication.

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Recent developments on polariton lasers

Zhang

Jin-qi

et al. 2022

Progress in Quantum Electronics

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Microcavity exciton polaritons

Zhang

Deng

2020

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Jiaqi Hu

Polariton Laser in the Bardeen-Cooper-Schrieffer Regime

Macroscopic transition metal dichalcogenides monolayers with uniformly high optical quality

Direct Generation of Radially Polarized Vector Vortex Beam with an Exciton-Polariton Laser

Recent developments on polariton lasers

Microcavity exciton polaritons

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