Phenolic condensation and facilitation of fluorescent carbon dot formation: A mechanism study

Kyueui Lee; Eunsook Park; Haesung A. Lee; Caroline Sugnaux; Mikyung Shin; Chan Jin Jeong; Jeehee Lee; Phillip B. Messersmith; Sung Young Park; Haeshin Lee

doi:10.1039/c7nr04170e

Phenolic condensation and facilitation of fluorescent carbon dot formation: A mechanism study

Kyueui Lee, Eunsook Park, Haesung A. Lee, Caroline Sugnaux, Mikyung Shin, Chan Jin Jeong, Jeehee Lee, Phillip B. Messersmith, Sung Young Park, Haeshin Lee

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34 Scopus citations

Abstract

Fluorescent carbon dots have received considerable attention as a result of their accessibility and potential applications. Although several prior studies have demonstrated that nearly any organic compound can be converted into carbon dots by chemical carbonization processes, mechanisms explaining the formation of carbon dots still remain unclear. Herein, we propose a seed-growth mechanism of carbon dot formation facilitated by ferulic acid, a widespread and naturally occurring phenolic compound in the seeds of Ocimum basilicum (basil). Ferulic acid triggers the local condensation of polysaccharide chains and forms catalytic core regions resulting in nanoscale carbonization. Our study indicates that carbon dots generated from natural sources might share the similar mechanism of phenolic compound mediated nanoscale condensation followed by core carbonization.

Original language	English
Pages (from-to)	16596-16601
Number of pages	6
Journal	Nanoscale
Volume	9
Issue number	43
DOIs	https://doi.org/10.1039/c7nr04170e
State	Published - 21 Nov 2017

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title = "Phenolic condensation and facilitation of fluorescent carbon dot formation: A mechanism study",

abstract = "Fluorescent carbon dots have received considerable attention as a result of their accessibility and potential applications. Although several prior studies have demonstrated that nearly any organic compound can be converted into carbon dots by chemical carbonization processes, mechanisms explaining the formation of carbon dots still remain unclear. Herein, we propose a seed-growth mechanism of carbon dot formation facilitated by ferulic acid, a widespread and naturally occurring phenolic compound in the seeds of Ocimum basilicum (basil). Ferulic acid triggers the local condensation of polysaccharide chains and forms catalytic core regions resulting in nanoscale carbonization. Our study indicates that carbon dots generated from natural sources might share the similar mechanism of phenolic compound mediated nanoscale condensation followed by core carbonization.",

author = "Kyueui Lee and Eunsook Park and Lee, {Haesung A.} and Caroline Sugnaux and Mikyung Shin and Jeong, {Chan Jin} and Jeehee Lee and Messersmith, {Phillip B.} and Park, {Sung Young} and Haeshin Lee",

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T1 - Phenolic condensation and facilitation of fluorescent carbon dot formation

T2 - A mechanism study

AU - Lee, Kyueui

AU - Park, Eunsook

AU - Lee, Haesung A.

AU - Sugnaux, Caroline

AU - Shin, Mikyung

AU - Jeong, Chan Jin

AU - Lee, Jeehee

AU - Messersmith, Phillip B.

AU - Park, Sung Young

AU - Lee, Haeshin

PY - 2017/11/21

Y1 - 2017/11/21

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AB - Fluorescent carbon dots have received considerable attention as a result of their accessibility and potential applications. Although several prior studies have demonstrated that nearly any organic compound can be converted into carbon dots by chemical carbonization processes, mechanisms explaining the formation of carbon dots still remain unclear. Herein, we propose a seed-growth mechanism of carbon dot formation facilitated by ferulic acid, a widespread and naturally occurring phenolic compound in the seeds of Ocimum basilicum (basil). Ferulic acid triggers the local condensation of polysaccharide chains and forms catalytic core regions resulting in nanoscale carbonization. Our study indicates that carbon dots generated from natural sources might share the similar mechanism of phenolic compound mediated nanoscale condensation followed by core carbonization.

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SN - 2040-3364

VL - 9

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JO - Nanoscale

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Phenolic condensation and facilitation of fluorescent carbon dot formation: A mechanism study

Abstract

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