Title: Subsurface Barrier Validation of a Colloidal Silica and a Jet Grouted Barrier with the SEAtrace System

Subsurface barriers are being constructed at both government and private sites to control hazardous material migration. The Department of Energy, in particular, is developing new barrier construction methods and materials for applications in saturated and unsaturated soils. These containment systems are meant to control high-risk contaminants that are too difficult to remove with current methods and/or pose a near-term, high risk to public health. Such systems are also implemented at sites where remediation techniques may have unintentionally mobilized contamination and threatened the water table. Since subsurface barriers are typically applied in high-risk circumstances, knowledge of their emplaced and long-term integrity is crucial. Current verification and monitoring practices (hydraulic testing, construction materials and methods QA) are limited in their ability to locate, discriminate, and resolve flaws in barrier construction. SEAtracem is a gaseous tracer verification and monitoring system developed to locate and estimate the size of flaws in subsurface barriers located above the water table. The system incorporates injection of a non-hazardous gaseous tracer in the barrier interior, multiple soil vapor sampling points located outside of the barrier, and an automated sampling and analysis system. SEAtraceTM is an autonomous, remotely accessible monitoring system intended for long duration, unattended operation. It not only collects and analyzes soil gas samples, but also applies real time data inversion to locate and size flaws in the barrier construction. The SEAtraceTM methodology was deployed at two test barrier installations sponsored by the Department of Energy Subsurface Contaminants Focus Area. The first was a small scale thinwall jet ~wouting barrier demonstration at the Groundwater Remediation Field Laboratory, Dover Air Force Base, and the second a large scale thickwall colloidal silica permeation grouted barrier at the Brookhaven National Laboratory. At the Dover site two test barriers and one buried known leak source were evaluated using the SEAtracem methodology. A prototype automated soil gas sampling and analysis system provided data that was analyzed on a desktop computer system. During these tests six non-engineered and one engineered flaw were detected in the barrier panels. These flaws indicated the presence of open areas in the barrier panels that allowed diffusion of tracer gas out into the soil surrounding the barriers. The buried leak source was located within 0.2m of its actual position. A fully integrated SEAtracem system was deployed to test a colloidal silica barrier at Brookhaven National Laboratory. This system incorporated 64 sampling locations, real-time data analysis, solar powered operation, and remote access via cellular phone communication. Eleven flaws were located by automated operation of the SEAtracem system. Other verification techniques such as geophysics, hydraulics, and peffluorocarbon gaseous tracers were used at both the Dover and Brookhaven test barriers. Results from these techniques were in good agreement when they could be compared. This report documents the design of the SEAtracem system, the numerical analysis that supports the evaluation of the inversion methodology, the design of the test installations, and the demonstrations at the Dover and Brookhaven sites.