Hazuki Kusano scite author profile

Hazuki Kusano

4Publications

1Citation Statement Received

92Citation Statements Given

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Osaka City University

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Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

et al. 2022

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The ability to modulate, tune, and control fluorescence colour has attracted much attention in photonics-related research fields. Thus far, it has been impossible to achieve fluorescence colour control (FCC) for material with a fixed structure, size, surrounding medium, and concentration. Here, we propose a novel approach to FCC using optical tweezers. We demonstrate an optical trapping technique using nanotextured Si (black-Si) that can efficiently trap polymer chains. By increasing the laser intensity, the local concentration of perylene-labelled water-soluble polymer chains increased inside the trapping potential. Accordingly, the excimer fluorescence of perylene increased while the monomer fluorescence decreased, evidenced by a fluorescence colour change from blue to orange. Using nanostructure-assisted optical tweezing, we demonstrate control of the relative intensity ratio of fluorescence of the two fluorophores, thus showing remote and reversible FCC of the polymer assembly.

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Frontispiz: Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

et al. 2022

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Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

et al. 2022

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The ability to modulate, tune, and control fluorescence colour has attracted much attention in photonics‐related research fields. Thus far, it has been impossible to achieve fluorescence colour control (FCC) for material with a fixed structure, size, surrounding medium, and concentration. Here, we propose a novel approach to FCC using optical tweezers. We demonstrate an optical trapping technique using nanotextured Si (black‐Si) that can efficiently trap polymer chains. By increasing the laser intensity, the local concentration of perylene‐labelled water‐soluble polymer chains increased inside the trapping potential. Accordingly, the excimer fluorescence of perylene increased while the monomer fluorescence decreased, evidenced by a fluorescence colour change from blue to orange. Using nanostructure‐assisted optical tweezing, we demonstrate control of the relative intensity ratio of fluorescence of the two fluorophores, thus showing remote and reversible FCC of the polymer assembly.

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Frontispiece: Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

et al. 2022

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Hazuki Kusano

Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

Frontispiz: Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

Frontispiece: Fluorescence Colour Control in Perylene‐Labeled Polymer Chains Trapped by Nanotextured Silicon

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