Functionalized open-ended vertically aligned carbon nanotube composite membranes with high salt rejection and enhanced slip flow for desalination

Vertically aligned carbon nanotubes (VACNTs) have shown unexpectedly high liquid flux. In this research, we investigated the effect of functionalization on the performance of VACNTs/polystyrene membranes, in which densely packed VACNTs with 2-11 nm inner diameters and areal density around 3.6 x 10(10) cm(-2) act as the only mass transport paths. The measured water permeance in the open-ended VACNTs membrane revealed an enhancement factor of three orders of magnitude higher than the continuum-based no-slip model. Different functional groups including carboxylic, glycine, octadecylamine, and 1,6-diaminohexane were attached to the VACNTs tips through carbodiimide coupling method, which were characterized by ATR-FTIR. Salt exclusion as a function of ion valence ratios, ionic strength, and pH value of the feed solution was studied. The results were strongly supported by Donnan exclusion mechanism. Interestingly, an increase in the concentration of salts from 500 to 5000 ppm improved the rejection, which is in contrast with other reports. The glycine functionalization was repeated two to three times to find the effect of the functional groups length as well as charge density on the rejection. pH-dependent measurements of glycine functionalized membrane demonstrated that both carboxyl and amide groups are responsible for the ion rejection characteristics of the membrane.

Automated summary

This research investigated the effect of functionalization on the performance of vertically aligned carbon nanotubes/polystyrene membranes. Different functional groups were attached to the nanotubes and their impact on water permeance and salt exclusion was studied. The results supported the Donnan exclusion mechanism and highlighted the role of carboxyl and amide groups in ion rejection characteristics of the membrane.