Selective coordination and localized polarization in graphene quantum dots: Detection of fluoride anions using ultra-low-field NMR relaxometry

The development of ultra-sensitive methods for detecting anions is limited by their low charge to radius ratios, microenvironment sensitivity, and pH sensitivity. In this paper, a magnetic sensor is devised that exploits the controllable and selective coordination that occurs between a magnetic graphene quantum dot (GQD) and fluoride anion (F-). The sensor is used to measure the change in relaxation time of aqueous solutions of magnetic GQDs in the presence of F- using ultra-low-field (118 mu T) nuclear magnetic resonance relaxometry. The method was optimized to produce a limit of detection of 10 nmol/L and then applied to quantitatively detect F- in domestic water samples. More importantly, the key factors responsible for the change in relaxation time of the magnetic GQDs in the presence of F- are revealed to be the selective coordination that occurs between the GQDs and F- as well as the localized polarization of the water protons. This striking finding is not only significant for the development of other magnetic probes for sensing anions but also has important ramifications for the design of contrast agents with enhanced relaxivity for use in magnetic resonance imaging. (C) 2021 Published by Elsevier B.V. on behalf of Chinese Chemical Society and Institute of Materia Medica, Chinese Academy of Medical Sciences.

Automated summary

A magnetic sensor utilizing magnetic graphene quantum dots and fluoride anions for ultra-sensitive detection was developed in this study, with an optimized method achieving a detection limit of 10 nmol/L. The key factors responsible for the change in relaxation time of magnetic GQDs in the presence of fluoride ions were revealed, indicating important implications for the development of magnetic probes and contrast agents for magnetic resonance imaging.