Skip Navigation
U.S. flag

An official website of the United States government

Dot gov

The .gov means it’s official.
Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

Https

The site is secure.
The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

Internet Explorer is no longer a supported browser.

This website may not display properly with Internet Explorer. For the best experience, please use a more recent browser such as the latest versions of Google Chrome, Microsoft Edge, and/or Mozilla Firefox. Thank you.

Your Environment. Your Health.

Northeastern University

Superfund Research Program

Remediation of Contaminated Groundwater by Solar-Powered Electrolysis

Project Leader: Akram N. Alshawabkeh
Grant Number: P42ES017198
Funding Period: 2010-2025
View this project in the NIH Research Portfolio Online Reporting Tools (RePORT)

Learn More About the Grantee

Visit the grantee's eNewsletter page Visit the grantee's eNewsletter page Visit the grantee's Twitter page Visit the grantee's Instagram page Visit the grantee's Facebook page Visit the grantee's Video page

Project Summary (2014-2020)

Akram Alshawabkeh, Ph.D., and his research team’s long-term goal is to develop novel, sustainable, solar-powered, and environmentally friendly technologies for remediation of contaminated groundwater, especially in karst regions. They will use solar panels to apply low direct electric currents through electrodes in wells to manipulate groundwater chemistry by electrolysis. Their target contaminants are chlorinated solvents, specifically trichloroethylene (TCE), but the process will also be designed to treat a mixture of contaminants. Two specific transformation mechanisms are evaluated: electrochemical reduction and chemical oxidation. Previously the researchers demonstrated that chemically reducing groundwater could be developed by iron anodes, leading to almost complete dechlorination of aqueous TCE. The researchers also evaluated chemical oxidation of TCE in groundwater by electrogenerated H2 and O2. Their objectives in this ongoing study are to understand and improve the process using innovative electrode systems for transformation of mixtures of contaminants under variable flow rates, assess the transformation pathways and their associated effects on groundwater toxicity, and measure the performance of the process in field-scale testing.

The researchers are conducting laboratory experiments in vertical column setups made of acrylic and limestone and in electrochemical reactors. They use the reactors to test innovative three-electrode treatment units to induce reducing or oxidizing conditions and investigate a novel two electrode system with polarity reversal to achieve oxidizing conditions. The researchers measure degradation and transformation products, as well as toxicity evolution, during the course of the process in batch electrochemical setups. In addition to a commonly used phenotypic in vitro assay, an innovative newly-developed fast and mechanistic toxicogenomics-based temporal gene or protein expression profiling technique is being employed. The variations of toxicity levels and mechanistic profiles during the course of the electrochemically-induced degradation disclose the potential causal agents and their links to the degradation pathways. For these laboratory tests, groundwater collected from Puerto Rico is mixed with target contaminants and used for testing. To facilitate translation of the process into field implementation, project researchers will conduct and measure the performance in a small field-scale test using a single well or multiple wells. Treatment units in the wells are connected to solar panels/controllers and different operation modes are tested. Observation wells are used to monitor changes.

The project researchers are developing a technology for sustainable remediation of contaminated groundwater. They are designing electrochemical reactors with innovative electrode systems for contaminant degradation and prove the reduction or elimination of toxicity during and after the treatment. Finally, the researchers are designing and measuring the performance of the technology in wells in a small-scale field study in aquifers in karst regions.

Back
to Top