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Quasi-BIC Modes in All-Dielectric Slotted Nanoantennas for Enhanced Er3+ Emission.


ABSTRACT: In the quest for new and increasingly efficient photon sources, the engineering of the photonic environment at the subwavelength scale is fundamental for controlling the properties of quantum emitters. A high refractive index particle can be exploited to enhance the optical properties of nearby emitters without decreasing their quantum efficiency, but the relatively modest Q-factors (Q ∼ 5-10) limit the local density of optical states (LDOS) amplification achievable. On the other hand, ultrahigh Q-factors (up to Q ∼ 109) have been reported for quasi-BIC modes in all-dielectric nanostructures. In the present work, we demonstrate that the combination of quasi-BIC modes with high spectral confinement and nanogaps with spacial confinement in silicon slotted nanoantennas lead to a significant boosting of the electromagnetic LDOS in the optically active region of the nanoantenna array. We observe an enhancement of up to 3 orders of magnitude in the photoluminescence intensity and 2 orders of magnitude in the decay rate of the Er3+ emission at room temperature and telecom wavelengths. Moreover, the nanoantenna directivity is increased, proving that strong beaming effects can be obtained when the emitted radiation couples to the high Q-factor modes. Finally, via tuning the nanoanntenna aspect ratio, a selective control of the Er3+ electric and magnetic radiative transitions can be obtained, keeping the quantum efficiency almost unitary.

SUBMITTER: Kalinic B 

PROVIDER: S-EPMC9936627 | biostudies-literature | 2023 Feb

REPOSITORIES: biostudies-literature

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Quasi-BIC Modes in All-Dielectric Slotted Nanoantennas for Enhanced Er<sup>3+</sup> Emission.

Kalinic Boris B   Cesca Tiziana T   Balasa Ionut Gabriel IG   Trevisani Mirko M   Jacassi Andrea A   Maier Stefan A SA   Sapienza Riccardo R   Mattei Giovanni G  

ACS photonics 20230118 2


In the quest for new and increasingly efficient photon sources, the engineering of the photonic environment at the subwavelength scale is fundamental for controlling the properties of quantum emitters. A high refractive index particle can be exploited to enhance the optical properties of nearby emitters without decreasing their quantum efficiency, but the relatively modest <i>Q</i>-factors (<i>Q</i> ∼ 5-10) limit the local density of optical states (LDOS) amplification achievable. On the other h  ...[more]

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