Hole-matrixed carbonylated graphene: Synthesis, properties, and highly-selective ammonia gas sensing

Here, the synthesis of holey carbonylated (C-ny) graphene derivative and its application for gas sensing is demonstrated. The carbonylation of graphene oxide leads to the 3-fold increase in the concentration of carbonyl groups' up to 9 at.% with a substantial elimination of other oxygen functionalities. Such a chemical modification is accompanied by the perforation of the graphene layer with the appearance of matrices of nanoscale holes, leading to corrugation of the layer and its sectioning into localized domains of the is-conjugated network. Combined with the predominant presence of carbonyls, granting the specificity in gas molecules adsorption, these features result in the enhanced gas sensing properties of Cny graphene at room temperature with a selective response to NH3. Opposite chemiresistive response towards ammonia when compared to other analytes, such as ethanol, acetone, CO2, is demonstrated for the C-ny graphene layer both in humid and dry air background. Moreover, a selective discrimination of all of the studied analytes is further approached by employing a vector signal generated by C-ny multi electrode chip. Comparing the experimental results with the calculations performed in framework of density functional theory, we clarify the effect of partial charge transfer caused by water and ammonia adsorption on the chemiresistive response. (C) 2020 Elsevier Ltd. All rights reserved.

Automated summary

This study demonstrates the synthesis of holey carbonylated graphene derivative and its application in gas sensing. The carbonylation of graphene oxide increases the concentration of carbonyl groups and enhances the gas sensing properties, with a selective response to ammonia. The presence of nanoscale holes and corrugation in the graphene layer play a key role in the improved gas sensing performance.