Blue, green, and red full-color ultralong afterglow in nitrogen-doped carbon dots

Carbon dots (CDs) with tunable emission colors and multiple emission modes are highly desirable in advanced optical anti-counterfeiting. Some pioneering efforts to trigger additional long-lived emission modes, nevertheless, did not perfectly solve the issue of printability and color-tunability in pr...

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Published inNanoscale Vol. 11; no. 14; pp. 6584 - 6590
Main Authors Lin, Cunjian, Zhuang, Yixi, Li, Wuhui, Zhou, Tian-Liang, Xie, Rong-Jun
Format Journal Article
LanguageEnglish
Published England Royal Society of Chemistry 04.04.2019
Subjects
Carbon dots
Coding
Color
Counterfeiting
Excitation spectra
Fluorescence
Fourier transforms
Image transmission
Infrared spectra
Inks
Phosphorescence
Photodynamic therapy
Photoelectrons
Recrystallization
Spectrum analysis
Synthesis
Transmission electron microscopy
Ultraviolet radiation
Wavelengths
Online AccessGet full text
ISSN2040-3364
2040-3372
2040-3372
DOI10.1039/C8NR09672D

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Abstract Carbon dots (CDs) with tunable emission colors and multiple emission modes are highly desirable in advanced optical anti-counterfeiting. Some pioneering efforts to trigger additional long-lived emission modes, nevertheless, did not perfectly solve the issue of printability and color-tunability in practical applications. Herein, we developed an encapsulating-dissolving-recrystallization route for the synthesis of CD-based anti-counterfeiting inks, and accordingly realized blue, green, and red full-color afterglow emissions from these CD-based inks when printed on paper. The printed inks simultaneously possessed triple emission modes including fluorescence (FL), delayed fluorescence (DF), and room-temperature phosphorescence (RTP), among which the long-lived emissions (DF and RTP) could be selectively activated by using different excitation wavelengths. We believe that the proposed synthetic route in this work may promote the development of multicolor-encoded and multiple-mode-integrated optical anti-counterfeiting systems, and will expand the application of CD-based materials to the fields of sensing, photodynamic therapy and bio-imaging.
AbstractList Carbon dots (CDs) with tunable emission colors and multiple emission modes are highly desirable in advanced optical anti-counterfeiting. Some pioneering efforts to trigger additional long-lived emission modes, nevertheless, did not perfectly solve the issue of printability and color-tunability in practical applications. Herein, we developed an encapsulating-dissolving-recrystallization route for the synthesis of CD-based anti-counterfeiting inks, and accordingly realized blue, green, and red full-color afterglow emissions from these CD-based inks when printed on paper. The printed inks simultaneously possessed triple emission modes including fluorescence (FL), delayed fluorescence (DF), and room-temperature phosphorescence (RTP), among which the long-lived emissions (DF and RTP) could be selectively activated by using different excitation wavelengths. We believe that the proposed synthetic route in this work may promote the development of multicolor-encoded and multiple-mode-integrated optical anti-counterfeiting systems, and will expand the application of CD-based materials to the fields of sensing, photodynamic therapy and bio-imaging.
Carbon dots (CDs) with tunable emission colors and multiple emission modes are highly desirable in advanced optical anti-counterfeiting. Some pioneering efforts to trigger additional long-lived emission modes, nevertheless, did not perfectly solve the issue of printability and color-tunability in practical applications. Herein, we developed an encapsulating-dissolving-recrystallization route for the synthesis of CD-based anti-counterfeiting inks, and accordingly realized blue, green, and red full-color afterglow emissions from these CD-based inks when printed on paper. The printed inks simultaneously possessed triple emission modes including fluorescence (FL), delayed fluorescence (DF), and room-temperature phosphorescence (RTP), among which the long-lived emissions (DF and RTP) could be selectively activated by using different excitation wavelengths. We believe that the proposed synthetic route in this work may promote the development of multicolor-encoded and multiple-mode-integrated optical anti-counterfeiting systems, and will expand the application of CD-based materials to the fields of sensing, photodynamic therapy and bio-imaging.Carbon dots (CDs) with tunable emission colors and multiple emission modes are highly desirable in advanced optical anti-counterfeiting. Some pioneering efforts to trigger additional long-lived emission modes, nevertheless, did not perfectly solve the issue of printability and color-tunability in practical applications. Herein, we developed an encapsulating-dissolving-recrystallization route for the synthesis of CD-based anti-counterfeiting inks, and accordingly realized blue, green, and red full-color afterglow emissions from these CD-based inks when printed on paper. The printed inks simultaneously possessed triple emission modes including fluorescence (FL), delayed fluorescence (DF), and room-temperature phosphorescence (RTP), among which the long-lived emissions (DF and RTP) could be selectively activated by using different excitation wavelengths. We believe that the proposed synthetic route in this work may promote the development of multicolor-encoded and multiple-mode-integrated optical anti-counterfeiting systems, and will expand the application of CD-based materials to the fields of sensing, photodynamic therapy and bio-imaging.
Author Zhou, Tian-Liang
Zhuang, Yixi
Lin, Cunjian
Xie, Rong-Jun
Li, Wuhui
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  surname: Zhuang
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BackLink https://www.ncbi.nlm.nih.gov/pubmed/30601528$$D View this record in MEDLINE/PubMed
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Snippet Carbon dots (CDs) with tunable emission colors and multiple emission modes are highly desirable in advanced optical anti-counterfeiting. Some pioneering...
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StartPage 6584
SubjectTerms Carbon dots
Coding
Color
Counterfeiting
Excitation spectra
Fluorescence
Fourier transforms
Image transmission
Infrared spectra
Inks
Phosphorescence
Photodynamic therapy
Photoelectrons
Recrystallization
Spectrum analysis
Synthesis
Transmission electron microscopy
Ultraviolet radiation
Wavelengths
Title Blue, green, and red full-color ultralong afterglow in nitrogen-doped carbon dots
URI https://www.ncbi.nlm.nih.gov/pubmed/30601528
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