Predicting Minimum Carbon Usage for PAC Adsorption of Trace Organic Contaminants from Natural Water

Abstract

Powdered activated carbon (PAC) is an excellent adsorbent for drinking water treatment of many trace organic contaminants. To evaluate and design a PAC adsorption process for a particular application, it is necessary to know the minimum (lowest economical) carbon (adsorbent) usage (MCU) defined thermodynamically. In this work, an explicit relationship is developed for predicting the MCU required for a desirable level of treatment of a target trace organic compound (TC). The adsorption processes considered are PAC slurry contactors idealized either as batch reactors, plug flow reactors, or continuous-flow stirred tank reactors. Comparing with the ones previously available in the literature, this newly developed relationship, as a predictive tool for practical uses as well, is more accurate because it does not need to assume that the MCU required for target TC removal can always reduce the competing background natural organic matter (NOM) to a level much less than the NOM initial/influent concentration. Applications of the relationship developed herein to PAC adsorption of typical trace organic contaminants in natural water are demonstrated with isotherm data from multiple literature sources.