Reduction of N-nitrosodimethylamine with granular iron and nickel enhancediron. 1. Pathways and kinetics

Laboratory batch and column tests were conducted to examine the reduction p athways and kinetics of N-nitrosodimethylamine (NDMA) by iron (Fe) and nick el-enhanced iron (Ni/Fe). A decrease in NDMA concentration and increases in dimethylamine (DMA) and ammonium were observed in both Fe and Ni/Fe column s. In the Fe column, the transformation process of NDMA appeared to follow pseudo-first-order kinetics with respect to NDMA, with an average half-life of 13+/-2 h. A small amount of nickel (0.25%) plated onto the iron greatly enhanced NDMA transformation rates. At early time the NDMA half-life in th e Ni/Fe column was 2 min but as time progressed the half-life increased to 4 min, and departures from first-order kinetics were observed. The mass bal ances of carbon in DMA and nitrogen in DMA and ammonium improved over time and reached 100% and 90%, respectively, after NDMA had passed through the c olumn for more than 50 pore volumes (PV). No 1,1-dimethylhydrazine, nitrous oxide, or methane were detected. Based on the electrochemical properties o f NDMA, the transformation mechanism of NDMA with Fe and Ni/Fe is postulate d to be catalytic hydrogenation, resulting in N-N bond breakdown to form DM A and ammonium as final products. Nickel, being a much stronger catalyst th an Fe for catalytic hydrogenation, resulted in a much faster reduction rate of NDMA. Of several methods tested, flushing the Ni/Fe column with 0.01 N sulfuric acid proved to be the most effective in restoring the Ni/Fe activi ty. The rapid transformation rate on Ni/Fe and the formation of nontoxic pr oducts indicate that this material may be applicable for treating NDMA cont aminated water, both in-situ and above ground.