Plasmonic Field-Guided Patterning of Hybrid Nanostructured Gratings for Their Plasmon-Mediated Optical Activities

Plasmonic Field-Guided Patterning of Hybrid Nanostructured Gratings for Their Plasmon-Mediated Optical Activities

Combining the nano- and macroworlds in nanophotonics is always a great challenge for manufacturing uniform plasmonic nanogratings to achieve overall extraordinary optical properties. This work reports a method to apply large-area nanostructured gratings to tune the fluorescence behavior of quantum d...

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Veröffentlicht in:ACS applied nano materials 2023-12, Vol.6 (24), p.22907-22915
Hauptverfasser: Huang, Xiaoping, Zhao, Yizhe, Wang, Ying, Liu, Ziang, Wang, Yucheng, Sun, Jingbo, Chen, Ruotong, Yang, Zhenyuan, Chen, Shizheng, Guo, Yongxin, Zhao, Qing
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container_end_page 22915
container_issue 24
container_start_page 22907
container_title ACS applied nano materials
container_volume 6
creator Huang, Xiaoping
Zhao, Yizhe
Wang, Ying
Liu, Ziang
Wang, Yucheng
Sun, Jingbo
Chen, Ruotong
Yang, Zhenyuan
Chen, Shizheng
Guo, Yongxin
Zhao, Qing
description Combining the nano- and macroworlds in nanophotonics is always a great challenge for manufacturing uniform plasmonic nanogratings to achieve overall extraordinary optical properties. This work reports a method to apply large-area nanostructured gratings to tune the fluorescence behavior of quantum dots (QDs). The angle-resolved spectral measurements on the Ag NPs-based nanogratings show that the transverse electric (TE) polarized incident light has suffered very little scattering, demonstrating photon energy is coupled with plasmonic energy on the Ag NP-based lines. This plasmon-induced energy transferring effect was further used to tune the plasmon-induced QD fluorescence on the nanogratings. The QDs on Ag NP-based nanogratings, exhibiting up to 5 times higher photoluminescence (PL) intensity than that on a random Ag NP-based film, are carefully characterized using PL spectroscopy. In contrast, the bare QDs directly coupled onto the nanogratings. Spectral measurements in combination with numerical simulations demonstrate that anisotropic plasmon-induced energy transfer in the nanocomposite system plays a critical role in overall fluorescent tuning. Such nanogratings exhibit multifunctionality, offering an efficient way to fabricate plasmonic nanograting-QD composites with great potential applications in plasmonic sensors, QD displays, and fluorescent spectroscopy.
doi_str_mv 10.1021/acsanm.3c04260
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