Nanoporous carbide-derived carbon with tunable pore size

Abstract

Porous solids are of great technological importance due to their ability to interact with gases and liquids not only at the surface, but throughout their bulk¹. Although large pores can be produced and well controlled in a variety of materials², nanopores in the range of 2 nm and below (micropores, according to IUPAC classification) are usually achieved only in carbons or zeolites. To date, major efforts in the field of porous materials have been directed towards control of the size, shape and uniformity of the pores. Here we demonstrate that porosity of carbide-derived carbons (CDCs)^{3,4,5,6,7,8,9} can be tuned with subångström accuracy in a wide range by controlling the chlorination temperature. CDC produced from Ti₃SiC₂ has a narrower pore-size distribution than single-wall carbon nanotubes or activated carbons; its pore-size distribution is comparable to that of zeolites. CDCs are produced at temperatures from 200–1,200 °C as a powder, a coating, a membrane or parts with near-final shapes, with or without mesopores. They can find applications in molecular sieves, gas storage, catalysts, adsorbents, battery electrodes, supercapacitors, water/air filters and medical devices.