“Brick-and-mortar” synthesis of free-standing mesoporous carbon nanocomposite membranes as supports of room temperature ionic liquids for CO2−N2 separation

Free-standing mesoporous carbon−graphitic carbon nanocomposite membranes with controllable pore size (7.3−11.3nm) were synthesized by the “brick-and-mortar” method, carbon black (CB) as “bricks” and soft-templated phenolic resin-based mesoporous carbon (MC) as the “mortar”. Immobilization of imidazolium-based room temperature ionic liquids ([Cnmim][Tf2N], n=2, 4, and 6) in the MC−CB membranes produced a series of supported ionic liquid membranes (SILMs) that are permselective for separation of CO2−N2 gas pair. Strong capillary forces resulting from the well-developed mesoporosity of the MC−CB membranes greatly enhanced the stability of the supported ionic liquids. This enabled the SILMs to operate under transmembrane pressures as high as 1000kPa without degrading their separation performance. This makes it possible to apply SILMs to high-pressure CO2 capture and separation processes, where high transmembrane pressure would greatly increase the permeate flux through the membranes. [Display omitted] •“Brick and mortar” synthesis of mesoporous carbon (MC−CB) nanocomposite membranes.•Narrow distribution of pores of MC−CB membranes.•Tailor the textural properties of MC−CB membranes by adjusting the brick/mortar ratio.•CO2-permselective supported ionic liquid membranes prepared by using MC−CB membranes.•Enhanced stability of the immobilized ionic liquids against transmembrane pressure.