- Program Areas
- Installation Energy and Water
- Environmental Restoration
- Munitions Response
- Resource Conservation and Resiliency
- Weapons Systems and Platforms
Demonstration and Validation of the Horizontal Reactive Media Treatment (HRX) Well for Managing Contaminant Plumes in Complex Geological Environments
Dr. Craig Divine | ARCADIS US, Inc.
The objective of this project is to field-validate the horizontal reactive media treatment (HRX) well, a new in situ remediation approach offering distinct advantages over traditional approaches for managing dissolved contaminants from source zones in complex geological settings. The approach uses directionally drilled horizontal wells filled with granular reactive media, such as zero valent iron (ZVI), installed in the direction of groundwater flow. Contaminant mass discharge from source zones can be dramatically reduced, which can be cost-effectively sustained over many years. By greatly reducing or eliminating source zone discharge, downgradient plumes can be effectively treated, possibly even achieving low water quality standards in a relatively short period of time. For many of the Department of Defense’s (DoD) sites, it is increasingly recognized that contaminant mass flux and discharge may represent the most appropriate measure of plume strength and potential migration risk; therefore, remedial objectives and technologies focusing primarily on long-term mass discharge reduction will be increasingly favored. The HRX well concept is particularly well-suited for sites where long-term mass discharge control is a primary performance objective.
The HRX well concept leverages natural “flow-focusing” behavior created by the strong well-to-aquifer permeability contrast to capture and passively treat proportionally large volumes of groundwater in situ. This flow-focusing captures a wide zone of impacted groundwater, which passively flows into the well through the screen at the upgradient portion of the well. Because the well is filled with a reactive media, impacted groundwater is treated in situ as it flows through the well. The treated groundwater then exits the well through the screen along the downgradient sections. The HRX well approach can provide rapid and dramatic reduction in contaminant mass discharge, and it requires no above-ground treatment or footprint and limited ongoing maintenance. Although the HRX well technology has not been field demonstrated to date, the concept has been patented and developed and tested through extensive numerical modeling and physical modeling (i.e., tank testing). This project will: (1) apply the HRX technology to control mass discharge at an appropriate DoD field site; (2) measure the actual hydraulic capture, ZVI treatment efficiency, and mass discharge reduction and compare to model-predicted performance; (3) assess overall technical and sustainability performance of the HRX well; and (4) develop a user-friendly design tool and guidance regarding technology applicability and limitations, anticipated performance, design and installation considerations, and costing.
The HRX well technology addresses many of the challenges inherent to remediation, including (1) costs and time requirements associated with hydraulic containment (e.g., conventional pump and treat); (2) effective delivery of injected reagent-based strategies; and (3) limitations associated with up-front costs and long-term hydraulics in flow-through permeable reactive barrier (PRB) treatment schemes. It has the potential to significantly improve the management of solvent source zones by providing a reliable method for controlling contaminant migration and mass discharge that requires little long-term maintenance, can be applied in complex geological settings, reduces impact on surface operations, and/or translates to significantly reduced lifecycle costs over currently available alternatives. An approach utilizing HRX wells for a typical trichloroethene (TCE) site may result in savings of approximately half the lifecycle costs. (Anticipated Project Completion - 2019)
Divine, et al., 2020. Field Demonstration of the Horizontal Reactive Media Treatment Well (HRX Well®) for Passive In-Situ Remediation. GWMR, 40(3): 42-554. DOI: doi.org/10.1111/gwmr.12407
Divine, C., J. Wright, J. Wang, J. McDonough, M. Kladias, M. Crimi, B.N. Nzeribe, J.F. Devlin, M. Lubrecht, D. Ombalski, W. Hodge, H. Voscott, and K. Gerber, 2018. The Horizontal Reactive Media Treatment Well (HRX Well®) for Passive In-Situ Remediation. Groundwater Monitoring & Remediation, 38(1):56-65. DOI: 10.1111/gwmr.12252
Divine, C., J. Wang, and M. Crimi. 2018. Reply to Comments. Groundwater Monitoring & Remediation, 38(3):15-16. DOI: 10.1111/gwmr.12288
Divine, C.E., J. Wright, J. Wang, J. McDonough, M. Kladias, M. Crimi, B.N. Nzeribe, J.F. Devlin, M. Lubrecht, D. Ombalski, W. Hodge, H. Voscott, and K. Gerber. 2018. The Horizontal Reactive Media Treatment Well (HRX Well®) for Passive In Situ Remediation: Design, Implementation, and Sustainability. Remediation Journal, 28(4):5-16.
Horst, J., C. Divine, M. Schnobrich, R. Oesterreich, J. Munholland. 2019. Groundwater Remediation in Low‐Permeability Settings: The Evolving Spectrum of Proven and Potential. Groundwater Monitoring & Remediation, 39(1):11-19.
DiMarco, A. 2016. M.S. Environmental Science and Engineering. Laboratory Testing and Validation of Directional Horizontal Wells for In Situ Groundwater Remediation. Graduated, May 2016.
Li, W. 2019. Meshfree Methods Based on Radial Basis Functions for Solving Partial Differential Equations: From Strong Form to Weakened Weak Form. PhD dissertation, Clarkson University, April 2019.
Nzeribe Nwedo, B. 2019. The Horizontal Reactive Media Treatment Well (HRX Well) for Passive In Situ Remediation. PhD dissertation, Clarkson University, April 2019.
U.S. Provisional Patent Application #62703336, Groundwater Treatment Systems and Methods (Treatment and Media Cartridges)
Points of Contact
Dr. Craig Divine
SERDP and ESTCP