Process optimization for producing ultrapure water with high resistivity and low total organic carbon.

In this work, we proposed a new combined process to produce high-purity water which can meet the requirement in many advanced high-tech applications. Here, we mainly focus on the rejection of ions and organic matters, which is characterized by conductivity/resistivity and total organic carbon (TOC), respectively. Ground water with TOC concentration of 373 µg/L and conductivity of 755 µS/cm was fed to the combined process. The effects of granular activated carbons (GACs) (Haycard and Calgon), ultravi- olet (UV) sterilizers (single-wavelength and multiwavelength) and ion-exchange (IX) resins (SMT200L, SMT100L and UP6040) on TOC removal efficiency were systematically investigated. We found that a multiwavelength UV185/254. GAC (Calgon) and IX resin (SMT100L) had a higher TOC removal efficiency. We then optimized ultrapure water system and assembled units to the system, which consisted of double- pass reverse osmosis (RO) membranes, IX resin (SMT100L), multiwavelength UV185/254 sterilizer, GAC (Calgon) + IX resin (SMT100L) and a final filter. The optimized ultrapure water system produced water with a high resistivity (18.2 MO-cm) and low TOC concentration (2.37 µg/L). This research provides a new available combined process for ultrapure water production design. [ABSTRACT FROM AUTHOR]