Fate and Transport of High Explosives in a Sandy Soil: Adsorption and Desorption |
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| Authors: | HIROSHI YAMAMOTO MATTHEW C MORLEY GERALD E SPEITEL JAY CLAUSEN |
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| Institution: | 1. Department of Civil Engineering University of Texas at Austin , Austin, TX, USA;2. Department of Civil Engineering University of Nebraska at Lincoln , Lincoln, NE, USA;3. AMEC Earth and Environmental Westford , MA, USA |
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| Abstract: | Several areas of the Massachusetts Military Reservation (MMR) have soils with significant levels of high explosives (HE) contamination because of a long history of training and range activities (such as open burning, open detonation, disposal, and artillery and mortar firing). Site-specific transport and attenuation mechanisms were assessed in sandy soils for three contaminants of concern: the nitramine hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX), and the nitroaromatics 2,4-dinitrotolune (2,4-DNT) and 2,4,6-trinitrotoluene (TNT). For all three contaminants, linear distribution coefficients (Kd) were dependent on the fraction of organic carbon in soil. The nitroaromatics sorbed much more strongly than RDX in both soils. Over 120 hours, the desorption rate of RDX from field contaminated surface soil was much slower than its sorption rate, with the desorption Kd (1.5 L/kg) much higher than Kd for sorption (0.37 L/kg). Desorption of 2,4-DNT was negligible over 120 hours. Thus, applying sorption-derived Kd values for transport modeling may significantly overestimate the flux of explosives from MMR soils. Based on multiple component column transport tests, RDX will be the most mobile of these contaminants in MMR soils. In saturated columns packed with uncontaminated soil, RDX broke through rapidly, whereas the nitroaromatics were significantly attenuated by irreversible sorption or abiotic transformations. |
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| Keywords: | High explosives adsorption desorption RDX TNT 2 4-dinitrotoluene |
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