Spatial Electron Acceptor Variability: Implications for Assessing Bioremediation Potential
Title:
Spatial Electron Acceptor Variability: Implications for Assessing Bioremediation Potential
Author:
Schreiber, Madeline E. Bahr, Jean M.
Appeared in:
Bioremediation journal
Paging:
Volume 3 (1999) nr. 4 pages 363-378
Year:
1999-10-01
Contents:
An extensive network of multilevel samplers was established in a hydrocarbon-contaminated wetland aquifer. Results of groundwater sampling for benzene, toluene, ethylbenzene, and xylenes (BTEX), and electron acceptors show that both pristine and contaminated groundwater have spatially variable chemical signatures, owing primarily to microbially mediated oxidation-reduction reactions. Due to these spatial variations, estimates of the efficiency of intrinsic bioremediation can vary significantly depending on how geochemical data are collected. Use of data collected from monitoring wells with screens longer than the vertical extent of the plume will generally underestimate the potential for intrinsic bioremediation for the most chemically active horizon of the plume. A comparison of pristine and contaminated redox patterns demonstrates that, although BTEX exerts the highest demand for electron acceptors, oxidation of natural organic matter also contributes to electron acceptor utilization. If natural and other non-BTEX losses of electron acceptors are ignored, the assimilative capacity, defined as the amount of a contaminant that can potentially be degraded with known amounts of electron acceptors, will be overestimated. Many numerical and analytical models designed to simulate biodegradation are directly or indirectly based on assimilative capacity estimates. Proper estimation of assimilative capacity is crucial if models are to accurately quantify solute concentrations over time and space.
Journal description