Designing outcoupling of light from nanostructured emitter in stratified medium with parasitic absorption

Anastasiia Sorokina; Harri Lipsanen; Nicklas Anttu

doi:10.1063/5.0088387

Designing outcoupling of light from nanostructured emitter in stratified medium with parasitic absorption

Anastasiia Sorokina, Harri Lipsanen, Nicklas Anttu^*

^*Corresponding author for this work

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Abstract

We demonstrate dipole-based modeling for designing nanostructured emitters in a stratified surrounding medium in the presence of parasitic absorption, while giving equivalent information about far-field emission as Lorentz reciprocity. We consider the challenging modeling case of a single nanowire with a parasitically absorbing planar top contact layer. The main advantage of our approach is the use of a near-field-to-far-field transformation (NFFT) adapted for stratified surrounding, which speeds up the simulations compared to approaches without such a NFFT. We show how the thickness of the contact layer, nanowire geometry, emitter position within the nanowire, refractive index of encapsulation layer, and orientation of the dipole moment of the emitter strongly affect the extraction of internally emitted photons.

Original language	English
Article number	223104
Journal	Journal of Applied Physics
Volume	131
Issue number	22
DOIs	https://doi.org/10.1063/5.0088387
Publication status	Published - 14 Jun 2022
MoE publication type	A1 Journal article-refereed

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title = "Designing outcoupling of light from nanostructured emitter in stratified medium with parasitic absorption",

abstract = "We demonstrate dipole-based modeling for designing nanostructured emitters in a stratified surrounding medium in the presence of parasitic absorption, while giving equivalent information about far-field emission as Lorentz reciprocity. We consider the challenging modeling case of a single nanowire with a parasitically absorbing planar top contact layer. The main advantage of our approach is the use of a near-field-to-far-field transformation (NFFT) adapted for stratified surrounding, which speeds up the simulations compared to approaches without such a NFFT. We show how the thickness of the contact layer, nanowire geometry, emitter position within the nanowire, refractive index of encapsulation layer, and orientation of the dipole moment of the emitter strongly affect the extraction of internally emitted photons.",

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AU - Sorokina, Anastasiia

AU - Lipsanen, Harri

AU - Anttu, Nicklas

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AB - We demonstrate dipole-based modeling for designing nanostructured emitters in a stratified surrounding medium in the presence of parasitic absorption, while giving equivalent information about far-field emission as Lorentz reciprocity. We consider the challenging modeling case of a single nanowire with a parasitically absorbing planar top contact layer. The main advantage of our approach is the use of a near-field-to-far-field transformation (NFFT) adapted for stratified surrounding, which speeds up the simulations compared to approaches without such a NFFT. We show how the thickness of the contact layer, nanowire geometry, emitter position within the nanowire, refractive index of encapsulation layer, and orientation of the dipole moment of the emitter strongly affect the extraction of internally emitted photons.

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JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 22

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Designing outcoupling of light from nanostructured emitter in stratified medium with parasitic absorption

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