One‐Step Covalent Immobilization of β‐Cyclodextrin on sp2 Carbon Surfaces for Selective Trace Amount Probing of Guests

The modification of solid surfaces with supramolecular hosts is a powerful method to tailor interfacial properties and confer chemical selectivity, but often involves multistep protocols that hinder facile upscaling. Here, the one‐step covalent modification of highly oriented pyrolytic graphite (HOP...

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Bibliographic Details
Published in:Advanced functional materials 2019-09, Vol.29 (36), p.n/a
Main Authors: Li, Zhi, Van Guyse, Joachim F. R., R. de la Rosa, Victor, Van Gorp, Hans, Walke, Peter, González, Miriam C. Rodríguez, Uji‐i, Hiroshi, Hoogenboom, Richard, De Feyter, Steven, Mertens, Stijn F. L.
Format: Article
Language:English
Subjects:
Atomic force microscopy
carbonaceous materials
Chemical sensors
Covalence
Cyclodextrins
Dopamine
Electrocatalysts
Electrochemical analysis
Electrodes
grafting
Inclusion complexes
Interfacial properties
Materials science
Microscopy
Organic chemistry
Pyrolytic graphite
Raman spectroscopy
Selectivity
Solid surfaces
Supramolecular compounds
surface modification
van der Waals solids
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Summary:The modification of solid surfaces with supramolecular hosts is a powerful method to tailor interfacial properties and confer chemical selectivity, but often involves multistep protocols that hinder facile upscaling. Here, the one‐step covalent modification of highly oriented pyrolytic graphite (HOPG) with a β‐cyclodextrin (β‐CD) derivative, which efficiently forms inclusion complexes with hydrophobic guests of suitable size, is demonstrated. The grafted β‐CD‐HOPG surface is investigated toward electrochemical detection of ferrocene and dopamine. The enrichment of the analytes at the electrode surface, through inclusion in β‐CD, leads to an enhanced electrochemical response and an improved detection limit. Furthermore, the modified β‐CD‐HOPG electrode discriminates analytes that form host–guest complexes with β‐CD against a 100‐fold higher background of electroactive substances that do not. Atomic force microscopy, scanning tunneling microscopy, and Raman spectroscopy confirm the covalent nature of the modification and reveal high stability toward solvent rinsing, ultrasonication, and temperatures up to 140 °C. The one‐step covalent modification therefore holds substantial promise for the routine production of inexpensive, yet robust and highly performant electrochemical sensors. Beyond electrochemical sensor development, our strategy is valuable to prepare materials where accurate spatial positioning of functional units and efficient current collection are crucial, e.g. in photoelectrodes or electrocatalysts. A simple, one‐step procedure is demonstrated to attach β‐cyclodextrin to a graphite surface. The modified surface can be used as an electrochemical sensor to detect hydrophobic molecules that fit in the cavity of β‐cyclodextrin. Much higher concentrations of hydrophilic molecules, which do not enter the cavity, do not hinder the detection.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201901488