||Estimating the Changing Rate of Anaerobic Reductive Dechlorination of Chlorinated Aliphatic Hydrocarbons in the Presence of Petroleum Hydrocarbons.
Moutoux, D. E. ;
Benson, L. A. ;
Swanson, M. A. ;
Wiedemeier, T. H. ;
Lenhart, J. ;
||National Risk Management Research Lab., Ada, OK. Subsurface Protection and Remediation Div. ;Parsons Engineering Science, Inc., Denver, CO. ;Colorado School of Mines, Golden. Div. of Environmental Science and Engineering. ;Air Force Center for Environmental Excellence, Brooks AFB, TX.
Chlorinated aliphatic hydrocarbons ;
Petroleum products ;
Ground water ;
Oxidation reduction reactions ;
Electron acceptors ;
Electron donors ;
Anaerobic processes ;
Biochemical reaction kinetics ;
Water pollution control ;
Cometabolic processes ;
BTEX(Benzene Toluene Ethylbenzene Xylene)
||Most EPA libraries have a fiche copy filed under the call number shown. Check with individual libraries about paper copy.
||Recent laboratory and field results demonstrate that different chlorinated aliphatic hydrocarbons (CAHs) ultimately can be transformed into innocuous chemical compounds in many aquifer systems. Transportation can be the result of either cometabolic reactions or reduction oxidation (redox) reactions. Several methodologies may be used to estimate the rate of reductive dechlorination of CAH compounds when they are being used to oxidize BTEX compounds. Both first-order and second-order approximations of CAH degradation rates can be useful in predicting CAH/BTEX plume behavior, although the second-order approximation will be especially useful in determining whether the system will first exhaust the available supply of electron donors (i.e., starve) or electron acceptors (i.e., strangle).
||Prepared in cooperation with Parsons Engineering Science, Inc., Denver, CO., Colorado School of Mines, Golden. Div. of Environmental Science and Engineering. and Air Force Center for Environmental Excellence, Brooks AFB, TX.
||%AUT:J. T. /Wilson ;J. E. /Hansen
|NTIS Title Notes
||68D; 99F; 57K
||PC A03/MF A01