Supramolecular recognition control of polyethylene glycol modified N-doped graphene quantum dots: tunable selectivity for alkali and alkaline-earth metal ions

Abstract: The graphene quantum dot based fluorescent probe community needs unambiguous evidence about the control on the ion selectivity. In this paper, polyethylene glycol modified N-doped graphene quantum dots (PN-GQDs) were synthesized by alkylation reaction between graphene quantum dots and organic halides. We demonstrate the tunable selectivity and sensitivity by controlling the supramolecular recognition through the length and the end group size of the polyether chain on PN-GQDs. The relationship formulae between … Show more

“…18,19 However, there are a series of problems for the direct carbonization of citric acid to face, such as complicated preparation process, harsh reaction conditions (such as strong acid/ alkali using), accurate pH control and tedious postprocessing, which may lead to great restrictions for the further biomedical applications of QDs. [20][21][22] To extend and improve the physical and chemical properties of GQDs, different modication methods have been applied, including surface functional groups modication, 23 heteroatoms doping 24,25 and formation of composite. 26,27 For example, the ways of functionalization with surface groups and heteroatoms doping (such as N,S) may signicantly transform the optical properties, quantum yields, chemical activities and electronics structure of GQDs, 28,29 which would provide interesting luminescent properties, such as pH-dependent and excitation-dependent photoluminescence (PL) behaviors.…”

Manganese(ii) enhanced fluorescent nitrogen-doped graphene quantum dots: a facile and efficient synthesis and their applications for bioimaging and detection of Hg²⁺ ions

“…18,19 However, there are a series of problems for the direct carbonization of citric acid to face, such as complicated preparation process, harsh reaction conditions (such as strong acid/ alkali using), accurate pH control and tedious postprocessing, which may lead to great restrictions for the further biomedical applications of QDs. [20][21][22] To extend and improve the physical and chemical properties of GQDs, different modication methods have been applied, including surface functional groups modication, 23 heteroatoms doping 24,25 and formation of composite. 26,27 For example, the ways of functionalization with surface groups and heteroatoms doping (such as N,S) may signicantly transform the optical properties, quantum yields, chemical activities and electronics structure of GQDs, 28,29 which would provide interesting luminescent properties, such as pH-dependent and excitation-dependent photoluminescence (PL) behaviors.…”

Manganese(ii) enhanced fluorescent nitrogen-doped graphene quantum dots: a facile and efficient synthesis and their applications for bioimaging and detection of Hg²⁺ ions

“…Whereas the peak ca.1363 cm −1 is attributed to D band is a breathing mode of the κ ‐point phonons of A 1g symmetry, hence it is correlated to confined defects and disorders . The obtained CTAB‐AuNRs‐GQDs nanocomposites show higher D/G intensity ratio (I D /I G =1.01) than pristine GQDs (I D /I G =0.97) may be owing to the increased sp 3 C atoms present in the CTAB alkyl chain …”

Graphene Quantum Dots Anchored Gold Nanorods for Electrochemical Detection of Glutathione

“…This was attributed to the fast mass‐transfer process in the quantum‐sized particles. This remarkable rapid response indicated application prospects in fast trace analysis . The PDADs also showed high selectivity.…”

Polydopamine dots as an ultrasensitive fluorescent probe switch for Cr(VI) in vitro