Grafting redox-active molecules on graphene oxide through a diamine linker: Length optimization for electron transfer

Rizwan Khan; Yuta Nishina

doi:10.1039/d1dt03197j

Grafting redox-active molecules on graphene oxide through a diamine linker: Length optimization for electron transfer

Rizwan Khan, Yuta Nishina

Research Core for Interdisciplinary Sciences

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Abstract

A redox-active molecule is grafted on graphene oxide (GO) via successive reactions. In the first step, GO is modified with diamine, which acts as a linker for the redox-active molecule. In the second step, the redox-active molecule is attached to the amino group of the linker by amide bond formation. Through these processes GO is partially reduced, enhancing its electrochemical properties. The structure of the functionalized GO is characterized by XPS, TGA, FTIR, and CV, and applied for electrodes in supercapacitors (SCs). The distance and direction of the redox-active molecule on the electrode affect the SC performance; ethylene diamine is the most promising linker to efficiently transfer electrons from the redox-active molecule to the electrode surface.

Original language	English
Pages (from-to)	1874-1878
Number of pages	5
Journal	Dalton Transactions
Volume	51
Issue number	5
DOIs	https://doi.org/10.1039/d1dt03197j
Publication status	Published - Feb 7 2022

ASJC Scopus subject areas

Inorganic Chemistry

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title = "Grafting redox-active molecules on graphene oxide through a diamine linker: Length optimization for electron transfer",

abstract = "A redox-active molecule is grafted on graphene oxide (GO) via successive reactions. In the first step, GO is modified with diamine, which acts as a linker for the redox-active molecule. In the second step, the redox-active molecule is attached to the amino group of the linker by amide bond formation. Through these processes GO is partially reduced, enhancing its electrochemical properties. The structure of the functionalized GO is characterized by XPS, TGA, FTIR, and CV, and applied for electrodes in supercapacitors (SCs). The distance and direction of the redox-active molecule on the electrode affect the SC performance; ethylene diamine is the most promising linker to efficiently transfer electrons from the redox-active molecule to the electrode surface.",

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AU - Khan, Rizwan

AU - Nishina, Yuta

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N2 - A redox-active molecule is grafted on graphene oxide (GO) via successive reactions. In the first step, GO is modified with diamine, which acts as a linker for the redox-active molecule. In the second step, the redox-active molecule is attached to the amino group of the linker by amide bond formation. Through these processes GO is partially reduced, enhancing its electrochemical properties. The structure of the functionalized GO is characterized by XPS, TGA, FTIR, and CV, and applied for electrodes in supercapacitors (SCs). The distance and direction of the redox-active molecule on the electrode affect the SC performance; ethylene diamine is the most promising linker to efficiently transfer electrons from the redox-active molecule to the electrode surface.

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Grafting redox-active molecules on graphene oxide through a diamine linker: Length optimization for electron transfer

Abstract

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