Simulated Rainfall-Driven Dissolution of TNT, Tritonal, Comp B and Octol Particles

Live-fire military training can deposit millimeter-sized particles of high explosives (HE) on surface soils when rounds do not explode as intended. Rainfall-driven dissolution of the particles then begins a process whereby aqueous HE solutions can enter the soil and groundwater as contaminants. We d...

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Bibliographic Details
Main Authors: Taylor, Susan, Lever, James H., Fadden, Jennifer, Perron, Nancy, Packer, Bonnie
Other Authors: ARMY ENVIRONMENTAL COMMAND ABERDEEN PROVING GROUND MD
Format: Text
Language:English
Published: 2009
Subjects:
Ammunition and Explosives
Solid Wastes Pollution and Control
Water Pollution and Control
*PARTICLE SIZE
*RAINFALL
*HIGH EXPLOSIVES
*SOILS
*GROUND WATER
OCTOL
RDX
PARTICLES
TRITONAL EXPLOSIVES
TNT
FIRING TESTS(ORDNANCE)
HE(HIGH EXPLOSIVES)
SURFACE SOILS
DISSOLUTION
COMP B EXPLOSIVES
SERDP COLLECTION
SERDP(STRATEGIC ENVIRONMENTAL RESEARCH AND DEVELOPMENT PROGRAM)
Cold Regions Research and Engineering Laboratory
Online Access:http://www.dtic.mil/docs/citations/ADA538061
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA538061
Description
Summary:Live-fire military training can deposit millimeter-sized particles of high explosives (HE) on surface soils when rounds do not explode as intended. Rainfall-driven dissolution of the particles then begins a process whereby aqueous HE solutions can enter the soil and groundwater as contaminants. We dripped water onto individual particles of TNT, Tritonal, Comp B and Octol to simulate how surface-deposited HE particles might dissolve under the action of rainfall and to use the data to verify a model that predicts HE dissolution as a function of particle size, particle composition and rainfall rate. Particle masses ranged from 1.1 to 17 mg and drip rates corresponded to nominal rainfall rates of 6 and 12 mm h 1. For the TNT and Tritonal particles, TNT solubility governed dissolution time scales, whereas the lower-solubility of RDX controlled the dissolution time of both RDX and TNT in Comp B. The large, low-solubility crystals of HMX slowed but did not control the dissolution of TNT in Octol. Predictions from a drop-impingement dissolution model agree well with dissolved-mass timeseries for TNT, Tritonal and Comp B, providing some confidence that the model will also work well when applied to the rainfall-driven, outdoor dissolution of these HE particles. Published in Chemosphere, v75 p1074-1081, 2009. Prepared in collaboration with U.S. Army Corps of Engineers Cold Regions Research and Engineering Laboratory, Hanover, NH. The original document contains color images.

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