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Effect of Temporal Changes in Air Injection Rate on Air Sparging Performance Groundwater Remediation
Author(s) -
Ben Neriah Asaf,
Paster Amir
Publication year - 2016
Publication title -
groundwater
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.84
H-Index - 94
eISSN - 1745-6584
pISSN - 0017-467X
DOI - 10.1111/gwat.12428
Subject(s) - environmental remediation , air sparging , secondary air injection , mixing (physics) , groundwater , environmental science , sparging , plume , contamination , groundwater remediation , environmental engineering , materials science , waste management , chemistry , geotechnical engineering , meteorology , geology , ecology , physics , quantum mechanics , engineering , biology
Abstract Air sparging ( AS ) is a commonly applied method for treating groundwater contaminated with volatile organic compounds ( VOCs ). When using a constant injection of air (continuous mode), a decline in remediation efficiency is often observed, resulting from insufficient mixing of contaminants at the pore scale. It is well known that turning the injection on and off (pulsed mode) may lead to a better remediation performance. In this article, we investigate groundwater mixing and contaminant removal efficiency in different injection modes (i.e., continuous and pulsed), and compare them to those achieved in a third mode, which we denote as “rate changing.” In this mode, injection is always on, and its rate is varying with time by abrupt changes. For the purpose of this investigation, we conducted two separate sets of experiments in a laboratory tank. In the first set of experiments, we used dye plume tracing to characterize the mixing induced by AS . In the second set of experiments, we contaminated the tank with a VOC and compared the remediation efficiency between the different injection modes. As expected, we observed that time‐variable injection modes led to enhanced mixing and contaminant removal. The decrease in contaminant concentrations during the experiment was found to be double for the “rate changing” and “pulsed” modes compared to the continuous mode, with a slightly preferable performance for the “rate changing” mode. These results highlight the critical role that mixing plays in AS , and support the need for further investigation of the proposed “rate changing” injection mode.