Metal‐Decorated Crown Ether‐Embedded Graphene Nanomeshes for Enhanced Molecular Adsorption

Abstract: Success in single molecule detection using graphene and graphene oxide has opened up numerous opportunities for other 2D carbon-based substrates to be used for applications in sensing and storage. Graphene nanomeshes, in particular, offer excellent platforms as filtration membranes. Molecular adsorption on pristine graphene is governed by weak van der Waals interactions, while considerable binding strengths can be achieved on defective, metal-doped and metal-decorated graphene. Hypothesizing that crown ether-e… Show more

“…33 These crown ether embedded graphenes are proposed to function as highly mechanically sensitive ion-permeable membranes 41 and novel two-dimensional materials with the capability to store HF, H 2 O and NH 3 molecules. 42 The dense arrangement of crown ethers within the graphene lattice has the potential to increase the density of active sites for metal ions, metal clusters, gas molecules, and so on. However, there is currently a lack of research concerning the compact arrangement of crown ethers within the graphene lattice and their impact on the properties of graphene.…”

Dense arrangement of crown ethers in graphene: novel graphitic carbon oxides with enhanced optoelectronic properties

“…33 These crown ether embedded graphenes are proposed to function as highly mechanically sensitive ion-permeable membranes 41 and novel two-dimensional materials with the capability to store HF, H 2 O and NH 3 molecules. 42 The dense arrangement of crown ethers within the graphene lattice has the potential to increase the density of active sites for metal ions, metal clusters, gas molecules, and so on. However, there is currently a lack of research concerning the compact arrangement of crown ethers within the graphene lattice and their impact on the properties of graphene.…”

Dense arrangement of crown ethers in graphene: novel graphitic carbon oxides with enhanced optoelectronic properties

Computational Studies on the Nitrogen-Doped Graphene Quantum Dots as Potential Sensor for Hazardous Gases

Nitrogen-Doped Graphene Quantum Dots for Efficient Detection of Toxic Gas