High Q-Factor Single-Mode Lasing in Inorganic Perovskite Microcavities with Microfocusing Field Confinement

Shuangshuang Tian; Qi Wang; Shuang Liang; Qi Han; Debao Zhang; Zhongmin Huang; Jiqiang Ning; Shiliang Mei; Wei Xie; Haibin Zhao; Xiang Wu; Jun Wang

doi:10.1021/acs.nanolett.3c04797

High Q-Factor Single-Mode Lasing in Inorganic Perovskite Microcavities with Microfocusing Field Confinement

Shuangshuang Tian, Qi Wang, Shuang Liang, Qi Han, Debao Zhang, Zhongmin Huang, Jiqiang Ning, Shiliang Mei, Wei Xie, Haibin Zhao^*, Xiang Wu^*, Jun Wang^*

^*Corresponding author for this work

Institute for Advanced Study in Precision Spectroscopy

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

7 Scopus citations

Abstract

The realization of high-Q single-mode lasing on the microscale is significant for the advancement of on-chip integrated light sources. It remains a challenging trade-off between Q-factor enhancement and light-field localization to raise the lasing emission rate. Here, we fabricated a zero-dimensional perovskite microcavity integrated with a nondamage pressed microlens to three-dimensionally tailor the intracavity light field and demonstrated linearly and nonlinearly (two-photon) pumped lasing by this microfocusing configuration. Notably, the microlensing microcavity experimentally achieves a high Q-factor (16700), high polarization (99.6%), and high Purcell factor (11.40) single-mode lasing under high-repetition pulse pumping. Three-dimensional light-field confinement formed by the microlens and plate microcavity simultaneously reduces the mode volume (∼3.66 μm³) and suppresses diffraction and transverse walk-off loss, which induces discretization on energy-momentum dispersions and spatial electromagnetic-field distributions. The Q factor and Purcell factor of our lasing come out on top among most of the reported perovskite microcavities, paving a promising avenue toward further studying electrically driven on-chip microlasers.

Original language	English
Pages (from-to)	1406-1414
Number of pages	9
Journal	Nano Letters
Volume	24
Issue number	4
DOIs	https://doi.org/10.1021/acs.nanolett.3c04797
State	Published - 31 Jan 2024

Keywords

high-Q microcavity
microlens
perovskite semiconductor
photonic lasing
two-photon pumped lasing

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10.1021/acs.nanolett.3c04797

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title = "High Q-Factor Single-Mode Lasing in Inorganic Perovskite Microcavities with Microfocusing Field Confinement",

abstract = "The realization of high-Q single-mode lasing on the microscale is significant for the advancement of on-chip integrated light sources. It remains a challenging trade-off between Q-factor enhancement and light-field localization to raise the lasing emission rate. Here, we fabricated a zero-dimensional perovskite microcavity integrated with a nondamage pressed microlens to three-dimensionally tailor the intracavity light field and demonstrated linearly and nonlinearly (two-photon) pumped lasing by this microfocusing configuration. Notably, the microlensing microcavity experimentally achieves a high Q-factor (16700), high polarization (99.6\%), and high Purcell factor (11.40) single-mode lasing under high-repetition pulse pumping. Three-dimensional light-field confinement formed by the microlens and plate microcavity simultaneously reduces the mode volume (∼3.66 μm3) and suppresses diffraction and transverse walk-off loss, which induces discretization on energy-momentum dispersions and spatial electromagnetic-field distributions. The Q factor and Purcell factor of our lasing come out on top among most of the reported perovskite microcavities, paving a promising avenue toward further studying electrically driven on-chip microlasers.",

keywords = "high-Q microcavity, microlens, perovskite semiconductor, photonic lasing, two-photon pumped lasing",

author = "Shuangshuang Tian and Qi Wang and Shuang Liang and Qi Han and Debao Zhang and Zhongmin Huang and Jiqiang Ning and Shiliang Mei and Wei Xie and Haibin Zhao and Xiang Wu and Jun Wang",

note = "Publisher Copyright: {\textcopyright} 2024 American Chemical Society.",

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doi = "10.1021/acs.nanolett.3c04797",

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T1 - High Q-Factor Single-Mode Lasing in Inorganic Perovskite Microcavities with Microfocusing Field Confinement

AU - Tian, Shuangshuang

AU - Wang, Qi

AU - Liang, Shuang

AU - Han, Qi

AU - Zhang, Debao

AU - Huang, Zhongmin

AU - Ning, Jiqiang

AU - Mei, Shiliang

AU - Xie, Wei

AU - Zhao, Haibin

AU - Wu, Xiang

AU - Wang, Jun

PY - 2024/1/31

Y1 - 2024/1/31

N2 - The realization of high-Q single-mode lasing on the microscale is significant for the advancement of on-chip integrated light sources. It remains a challenging trade-off between Q-factor enhancement and light-field localization to raise the lasing emission rate. Here, we fabricated a zero-dimensional perovskite microcavity integrated with a nondamage pressed microlens to three-dimensionally tailor the intracavity light field and demonstrated linearly and nonlinearly (two-photon) pumped lasing by this microfocusing configuration. Notably, the microlensing microcavity experimentally achieves a high Q-factor (16700), high polarization (99.6%), and high Purcell factor (11.40) single-mode lasing under high-repetition pulse pumping. Three-dimensional light-field confinement formed by the microlens and plate microcavity simultaneously reduces the mode volume (∼3.66 μm3) and suppresses diffraction and transverse walk-off loss, which induces discretization on energy-momentum dispersions and spatial electromagnetic-field distributions. The Q factor and Purcell factor of our lasing come out on top among most of the reported perovskite microcavities, paving a promising avenue toward further studying electrically driven on-chip microlasers.

AB - The realization of high-Q single-mode lasing on the microscale is significant for the advancement of on-chip integrated light sources. It remains a challenging trade-off between Q-factor enhancement and light-field localization to raise the lasing emission rate. Here, we fabricated a zero-dimensional perovskite microcavity integrated with a nondamage pressed microlens to three-dimensionally tailor the intracavity light field and demonstrated linearly and nonlinearly (two-photon) pumped lasing by this microfocusing configuration. Notably, the microlensing microcavity experimentally achieves a high Q-factor (16700), high polarization (99.6%), and high Purcell factor (11.40) single-mode lasing under high-repetition pulse pumping. Three-dimensional light-field confinement formed by the microlens and plate microcavity simultaneously reduces the mode volume (∼3.66 μm3) and suppresses diffraction and transverse walk-off loss, which induces discretization on energy-momentum dispersions and spatial electromagnetic-field distributions. The Q factor and Purcell factor of our lasing come out on top among most of the reported perovskite microcavities, paving a promising avenue toward further studying electrically driven on-chip microlasers.

KW - high-Q microcavity

KW - microlens

KW - perovskite semiconductor

KW - photonic lasing

KW - two-photon pumped lasing

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JO - Nano Letters

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ER -

High Q-Factor Single-Mode Lasing in Inorganic Perovskite Microcavities with Microfocusing Field Confinement

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Keywords

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