Engineering in situ growth of Au nanoclusters on hydrophilic paper fibres for fluorescence calligraphy-based chemical logic gates and information encryption

Gold nanoclusters (AuNCs) are a type of rising-star fluorescence nanomaterials, but their properties and applications are hindered by the multi-step synthesis and purification routes, as well as the lack of desired supporting substrates. To enhance optical performance and working efficiency, the syn...

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Veröffentlicht in:	Nanoscale horizons 2024-10, Vol.9 (11), p.2007-2015
Hauptverfasser:	Luo, Jun Jiang, Guo, Dun Ying, Qu, Zi Bo, Luo, Hong Qun, Li, Nian Bing, Zou, Hao Lin, Li, Bang Lin
Format:	Artikel
Sprache:	eng
Schlagworte:	Aqueous solutions Astrochemistry Calligraphy Chemical reduction Chemical synthesis Chloroauric acid Encryption Fluorescence Glutathione Hydrophilicity Logic circuits Nanoclusters Nanomaterials Optical properties Oxidation Reagents
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container_end_page	2015
container_issue	11
container_start_page	2007
container_title	Nanoscale horizons
container_volume	9
creator	Luo, Jun Jiang Guo, Dun Ying Qu, Zi Bo Luo, Hong Qun Li, Nian Bing Zou, Hao Lin Li, Bang Lin
description	Gold nanoclusters (AuNCs) are a type of rising-star fluorescence nanomaterials, but their properties and applications are hindered by the multi-step synthesis and purification routes, as well as the lack of desired supporting substrates. To enhance optical performance and working efficiency, the synthesis and applications of AuNCs are suggested to be merged with emerging substrates. Herein, glutathione-modified hydrophilic rice papers are incubated in chloroauric acid aqueous solutions, and the oxidation-reduction reaction between glutathione and Au ions enables the formation of fluorescent AuNCs on the solid fibres of rice papers. The growth of fluorescent AuNCs on rice papers resulted in eye-catching fluorescence tracks, similar to traditional Chinese conventional calligraphy; thus, this fluoresence calligraphy is defined in this work. The entire process, including synthesis and signal responses, is extremely simple, rapid, and repeatable. Moreover, the diversity of additive chemical reagents in the studied rice papers resulted in responsive fluorescence calligraphy, and the as-synthesized AuNC materials exhibited high reliability and optical stability. Significantly, with the integration of synchronous formation and application of Au nanoclusters on hydrophilic paper substrates, high-performance logical gates and information encryption systems were constructed, remarkably facilitating the progress of molecular sensing and important information transmission.
doi_str_mv	10.1039/d4nh00307a
format	Article
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subjects	Aqueous solutions Astrochemistry Calligraphy Chemical reduction Chemical synthesis Chloroauric acid Encryption Fluorescence Glutathione Hydrophilicity Logic circuits Nanoclusters Nanomaterials Optical properties Oxidation Reagents
title	Engineering in situ growth of Au nanoclusters on hydrophilic paper fibres for fluorescence calligraphy-based chemical logic gates and information encryption
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