Abstract
Current techniques used to monitor in situ degradation of organic contaminants require time intervals of days to months to measure significant changes in concentration. In addition, these methods are unable to monitor mineralization or measure absolute degradation of complex mixed wastes. The ability to continuously and definitively monitor mineralization (conversion to CO 2 and H 2O) would greatly enhance the ability to study the fate of contaminants. The objectives of this study were to show that in environments with appropriate background δ 13C signatures, simultaneous measurement of CO 2 production and δ 13C signatures of the produced CO 2 will allow both the quantification and qualification of contaminant mineralization. In laboratory microcosm studies the mineralization of hexadecane was monitored by both traditional 14C radiorespirometry techniques and by measuring the δ 13C ratio and total amount of produced CO 2. The total mass of hexadecane mineralized determined by each technique was statistically the same. More importantly, the first order rate constants calculated from the respective mineralization curves were virtually identical. These results indicate that stable carbon isotope ratios are an appropriate means of monitoring aerobic mineralization of contaminants in environments in which differences in δ 13C ratios exist between contaminant and natural organic matter.
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