Lasing Action from Quasi-Propagating Modes

Max J.H. Tan; Jeong Eun Park; Francisco Freire-Fernández; Jun Guan; Xitlali G. Juarez; Teri W. Odom

doi:10.1002/adma.202203999

Lasing Action from Quasi-Propagating Modes

Max J.H. Tan, Jeong Eun Park, Francisco Freire-Fernández, Jun Guan, Xitlali G. Juarez, Teri W. Odom^*

^*Corresponding author for this work

Chemistry

Research output: Contribution to journal › Article › peer-review

19 Scopus citations

Abstract

Band edges at the high symmetry points in reciprocal space of periodic structures hold special interest in materials engineering for their high density of states. In optical metamaterials, standing waves found at these points have facilitated lasing, bound-states-in-the-continuum, and Bose–Einstein condensation. However, because high symmetry points by definition are localized, properties associated with them are limited to specific energies and wavevectors. Conversely, quasi-propagating modes along the high symmetry directions are predicted to enable similar phenomena over a continuum of energies and wavevectors. Here, quasi-propagating modes in 2D nanoparticle lattices are shown to support lasing action over a continuous range of wavelengths and symmetry-determined directions from a single device. Using lead halide perovskite nanocrystal films as gain materials, lasing is achieved from waveguide-surface lattice resonance (W-SLR) modes that can be decomposed into propagating waves along high symmetry directions, and standing waves in the orthogonal direction that provide optical feedback. The characteristics of the lasing beams are analyzed using an analytical 3D model that describes diffracted light in 2D lattices. Demonstrations of lasing across different wavelengths and lattice designs highlight how quasi-propagating modes offer possibilities to engineer chromatic multibeam emission important in hyperspectral 3D sensing, high-bandwidth Li-Fi communication, and laser projection displays.

Original language	English (US)
Article number	2203999
Journal	Advanced Materials
Volume	34
Issue number	34
DOIs	https://doi.org/10.1002/adma.202203999
State	Published - Aug 25 2022

Funding

M.J.H.T. and J.‐E.P. contributed equally to this work. This work was supported by the National Science Foundation (NSF) under DMR‐1904385 (M.J.H.T., J.E.P., J.G., F.F.F., X.G.J., and T.W.O.) and the Vannevar Bush Faculty Fellowship from DOD under N00014‐17‐1‐3023 (J.G. and T.W.O.). J.E.P. was also supported by National Research Foundation of Korea's Basic Science Research Program funded by the Korean Ministry of Education (2020R1A6A3A03039591). This work used the Northwestern University Micro/Nano Fabrication Facility (NUFAB) and EPIC facility of Northwestern University's NUANCE Center, which are supported by the Soft and Hybrid Nanotechnology Experimental (SHyNE) Resource (ECCS‐2025633), the International Institute for Nanotechnology (IIN), and Northwestern's Materials Research Science and Engineering Center (MRSEC; DMR‐1720139). This research was supported in part by the Quest high‐performance computing facility at Northwestern University, which is jointly supported by the Office of the Provost, the Office for Research, and Northwestern University Information Technology.

Keywords

2D plasmonic lattices
multibeam lasers
multicolor lasers
perovskite nanocrystals
quasi-propagating modes

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

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title = "Lasing Action from Quasi-Propagating Modes",

abstract = "Band edges at the high symmetry points in reciprocal space of periodic structures hold special interest in materials engineering for their high density of states. In optical metamaterials, standing waves found at these points have facilitated lasing, bound-states-in-the-continuum, and Bose–Einstein condensation. However, because high symmetry points by definition are localized, properties associated with them are limited to specific energies and wavevectors. Conversely, quasi-propagating modes along the high symmetry directions are predicted to enable similar phenomena over a continuum of energies and wavevectors. Here, quasi-propagating modes in 2D nanoparticle lattices are shown to support lasing action over a continuous range of wavelengths and symmetry-determined directions from a single device. Using lead halide perovskite nanocrystal films as gain materials, lasing is achieved from waveguide-surface lattice resonance (W-SLR) modes that can be decomposed into propagating waves along high symmetry directions, and standing waves in the orthogonal direction that provide optical feedback. The characteristics of the lasing beams are analyzed using an analytical 3D model that describes diffracted light in 2D lattices. Demonstrations of lasing across different wavelengths and lattice designs highlight how quasi-propagating modes offer possibilities to engineer chromatic multibeam emission important in hyperspectral 3D sensing, high-bandwidth Li-Fi communication, and laser projection displays.",

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AB - Band edges at the high symmetry points in reciprocal space of periodic structures hold special interest in materials engineering for their high density of states. In optical metamaterials, standing waves found at these points have facilitated lasing, bound-states-in-the-continuum, and Bose–Einstein condensation. However, because high symmetry points by definition are localized, properties associated with them are limited to specific energies and wavevectors. Conversely, quasi-propagating modes along the high symmetry directions are predicted to enable similar phenomena over a continuum of energies and wavevectors. Here, quasi-propagating modes in 2D nanoparticle lattices are shown to support lasing action over a continuous range of wavelengths and symmetry-determined directions from a single device. Using lead halide perovskite nanocrystal films as gain materials, lasing is achieved from waveguide-surface lattice resonance (W-SLR) modes that can be decomposed into propagating waves along high symmetry directions, and standing waves in the orthogonal direction that provide optical feedback. The characteristics of the lasing beams are analyzed using an analytical 3D model that describes diffracted light in 2D lattices. Demonstrations of lasing across different wavelengths and lattice designs highlight how quasi-propagating modes offer possibilities to engineer chromatic multibeam emission important in hyperspectral 3D sensing, high-bandwidth Li-Fi communication, and laser projection displays.

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Lasing Action from Quasi-Propagating Modes

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