Enhanced Dissolution of Trichloroethene: Effect of Carbohydrate Addition and Fermentation Processes

• Published in: Journal of environmental engineering (New York, N.Y.) Vol. 135; no. 9; pp. 861 - 868
• Main Authors: Nelson, D. K, Novak, P. J
• Format: Journal Article
• Language: English
• Published: Reston, VA American Society of Civil Engineers 01.09.2009
• Subjects: Applied sciences; Biological and physicochemical phenomena; Exact sciences and technology; Groundwaters; Natural water pollution; Pollution; TECHNICAL PAPERS; Water treatment and pollution; Biodegradation; Mixing; Solubility; Partition coefficient; Fermentation; Dissolution; Nonaqueous phase liquid; Modeling; Mass transfer; Groundwater pollution; Emulsion; Decontamination; Nonaqueous phase liquids; Water pollution; Remedial action; Bioremediation; Biological treatment; Ground water; Ethylene(trichloro)
• ISSN: 0733-9372; 1943-7870
• DOI: 10.1061/(ASCE)EE.1943-7870.0000042

Remediation of source areas is challenging because lingering contaminants are often present as nonaqueous phase liquid (NAPL) and sorbed mass, and therefore difficult to remove via biodegradation or other commonly used remedial methods. Experimental results indicate that enhanced dissolution of a model NAPL, trichloroethene (TCE), can occur through the addition and/or subsequent fermentation of a dilute molasses solution. Enhanced mass transfer occurs by two mechanisms, depending upon whether the molasses solution is fresh or has fermented. The addition of fresh molasses worked to increase TCE solubility ( >200% ) , thereby increasing mass transfer from the NAPL phase. Mixing TCE NAPL with a fermented molasses solution, however, increased TCE mass flux via the formation of a NAPL/aqueous phase emulsion. In addition, fermented liquid may have also decreased the soil partitioning coefficient ( Kd ) of TCE, indicating that enhanced transfer of sorbed mass to the aqueous phase could also occur in the presence of fermented molasses. These results provide guidance on how remedial systems may be optimized to increase NAPL and sorbed-mass dissolution and are therefore important, particularly when bioremediation is used to polish residual source zones.