For integrated photonics, waveguide structures based on rare-earth-activated glasses are potential candidates for implementing compact integrated light sources and amplifiers. However, rare-earth ions (REs) possess low absorption cross-section, and this limits the light emission and amplification efficiency. As long as the REs are involved, there are other phenomena detrimental to their luminescence quantum yield including ion-ion interactions and non-radiative relaxation processes. To solve such problems, photonic glass-ceramics can be strategic solutions. Transparent glass-ceramics combine interesting properties of both amorphous and crystalline phases and offer specific characteristics of capital importance in photonics. More important, photonic glass-ceramics can tailor and enhance the spectroscopic properties of the rare-earth ions depending on their compositions and nature. In this work, we studied SnO2-nanocrystal-based transparent glass-ceramic planar waveguides activated by rare-earths to give solutions for the problems mentioned above and enhance the rare-earth luminescence efficiency for integrated photonics. SiO2–SnO2:Er3+ planar waveguides containing 30 mol% SnO2 nanocrystals were fabricated by sol-gel method and dip-coating technique. The planar waveguides were assessed by various characterization techniques to ensure the applicability of such glass-ceramics for integrated photonics. The experimental assessment of the SiO2–SnO2:Er3+ planar waveguides focused on the key considered photonic characteristics including the structural, morphological, spectroscopic, and especially optical waveguiding properties. The photoluminescence measurements put in evidence the role of SnO2 nanocrystals as efficient Er3+ luminescence sensitizers. Moreover, the incorporation of Er3+ ions in SnO2 nanocrystals was demonstrated to reduce the effect of non-radiative relaxation processes on the luminescence of the Er3+ ions and thus led to higher luminescence efficiency. Majority of the Er3+ ions (97%) was confirmed to be imbedded in the SnO2 nanocrystals. The SiO2–SnO2:Er3+ glass-ceramic planar waveguides have confined propagation modes, step-index profile with high confinement of 82% at 1542 nm and especially, low losses of 0.6 ± 0.2 dB/cm at 1542 nm.

Assessment of SnO2-nanocrystal-based luminescent glass-ceramic waveguides for integrated photonics / Tran, T. N. L.; Armellini, C.; Varas, S.; Carpentiero, A.; Chiappini, A.; Gluchowski, P.; Iacob, E.; Ischia, G.; Scotognella, F.; Bollani, M.; Lukowiak, A.; Righini, G. C.; Ferrari, M.; Chiasera, A.. - ELETTRONICO. - 47:4(2021), pp. 5534-5541. [10.1016/j.ceramint.2020.10.137]

Assessment of SnO2-nanocrystal-based luminescent glass-ceramic waveguides for integrated photonics

Scotognella F.;
2021

Abstract

For integrated photonics, waveguide structures based on rare-earth-activated glasses are potential candidates for implementing compact integrated light sources and amplifiers. However, rare-earth ions (REs) possess low absorption cross-section, and this limits the light emission and amplification efficiency. As long as the REs are involved, there are other phenomena detrimental to their luminescence quantum yield including ion-ion interactions and non-radiative relaxation processes. To solve such problems, photonic glass-ceramics can be strategic solutions. Transparent glass-ceramics combine interesting properties of both amorphous and crystalline phases and offer specific characteristics of capital importance in photonics. More important, photonic glass-ceramics can tailor and enhance the spectroscopic properties of the rare-earth ions depending on their compositions and nature. In this work, we studied SnO2-nanocrystal-based transparent glass-ceramic planar waveguides activated by rare-earths to give solutions for the problems mentioned above and enhance the rare-earth luminescence efficiency for integrated photonics. SiO2–SnO2:Er3+ planar waveguides containing 30 mol% SnO2 nanocrystals were fabricated by sol-gel method and dip-coating technique. The planar waveguides were assessed by various characterization techniques to ensure the applicability of such glass-ceramics for integrated photonics. The experimental assessment of the SiO2–SnO2:Er3+ planar waveguides focused on the key considered photonic characteristics including the structural, morphological, spectroscopic, and especially optical waveguiding properties. The photoluminescence measurements put in evidence the role of SnO2 nanocrystals as efficient Er3+ luminescence sensitizers. Moreover, the incorporation of Er3+ ions in SnO2 nanocrystals was demonstrated to reduce the effect of non-radiative relaxation processes on the luminescence of the Er3+ ions and thus led to higher luminescence efficiency. Majority of the Er3+ ions (97%) was confirmed to be imbedded in the SnO2 nanocrystals. The SiO2–SnO2:Er3+ glass-ceramic planar waveguides have confined propagation modes, step-index profile with high confinement of 82% at 1542 nm and especially, low losses of 0.6 ± 0.2 dB/cm at 1542 nm.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11583/2985370