MTBE, synthetic resin adsorbents wi

MTBE, synthetic resin adsorbents with high surface area and tun- able pore structure have proved to be the promising candidates [20]. Synthetic carbonaceous resins Ambersorb 563 and 572 were found to have adsorption capacities three to five times greater than activated carbon Filtrasorb 400 at an MTBE equilibrium concentra- tion of 1 mg/l [8]. Shih et al. [17] concluded that Ambersorb 563 was a superior adsorbent for the removal of MTBE from drinking water in terms of adsorbent usage rate, integrated column capacity and the cost. Synthetic polymeric resins Amberlite XAD-4, XAD-7 and Optipore L493 were also found to be effective for the adsorption of aqueous MTBE [15,18,19].
Polymeric resin adsorbents are usually classified into three cat- egories: gel-type, macroporous and postcrosslinked [21]. Gel-type resins with nonporous structure and low surface area are seldom used as the adsorbents for organic solutes. Macroporous resins are capable of effectively adsorbing organic pollutants, due to their porous polymeric matrix. For small organic molecules such as MTBE, however, adsorption generally occurs in the micropores of the resins through van der Waals forces, dipole–dipole interactions, and/or hydrogen bonding [22,23]. It is noteworthy that the pore structure as well as the micropore volume of polymeric adsorbents can be finely tuned by postcrosslinking using chloromethylated