Project Summary

Mission Statement

The Anacostia River has been subjected to dredging, filling, contamination, and other human influences for over 200 years. The result of these activities is that the river has been seriously degraded from its natural state. Many groups have been working to reduce the effects of environmental degradation on the water quality and living resources of the Anacostia River, primarily by focusing on toxic contamination in river sediments. Other sources of contaminants to the Anacostia, including those from combined sewage outfalls and from ground water, are beginning to attract attention from investigators interested in addressing the environmental problems in the area.

Ground-water hydrogeology in the lower Anacostia tidal watershed is not well characterized, and is possibly a source of contaminants to the river. Because of the urban nature of the watershed and the long history of industrial and residential development in the area, it is likely that ground water in the area is contaminated. However, little is known about the types of non-point source contaminants in the ground water, the characteristics of ground-water flow, or the volumetric flux of ground water and associated contaminants to the river. Because of the many modifications to the river system (including bulkheads, dredging, filling, engineered wetlands, storm drains, and leaky infrastructure), ground-water interactions with the river are expected to be complex and difficult to characterize. It is therefore important to use a wide variety of investigative tools to help characterize the ground-water flow system, the ground-water quality, and the ground-water / surface-water interactions.

The overall goal of the proposed project is to develop an understanding of the hydrogeologic framework, to determine the extent of ground-water/surface-water interactions, and to estimate the contributions of contaminants from the ground water to the lower tidal Anacostia River.

Location

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Study area	Site locations

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Project Activities

The proposed project is a multi-year investigation designed to use existing data and to collect new data to achieve the objective in a cost-effective manner. The following approach is proposed to help achieve the objective:

1. Develop a series of hydrogeologic cross sections in the lower Anacostia tidal watershed. Because this is a highly urbanized area, it is anticipated that a lot of engineering information on the geology of the area will be available in the records of various public works agencies for the District of Columbia. The urban character of the study area will complicate this task as well, because nearly all of the shallow geologic features will have been disturbed by the dredging, filling, and construction activities that have made the lower Anacostia watershed what it is today. The accuracy of the hydrogeologic cross sections will therefore be highly dependent on the availability and usefulness of the existing records, and on the diligence of the investigators in obtaining and synthesizing information from these records.

2. Drill new wells to be used as part of the ground-water monitoring network in the lower Anacostia watershed. This task is an essential part of the project, and will be done in close cooperation with the D.C. Department of Health (DCDOH). Well locations will be based on DCDOH needs, and wells will be installed in accordance with DCDOH criteria. Initial plans for the first year of the study are to drill six or more borings: two clusters of two wells each, one 50-ft stand-alone well, and one or more borings in river sediments drilled with the USGS Hoverprobe at sites chosen by DCDOH. Wells will be constructed using four-inch PVC well materials, and will be installed at approximately 20 and 50 feet below ground surface at each site. The wells will be finished with either flush mounting or protective steel casing, depending on the location. Borehole geophysical data (gamma logs) will be collected for each well that can be accessed by the appropriate equipment. Continuous lithologic core will be collected to about 50 ft below ground surface prior to installing monitoring wells. Some of the lithologic samples collected during the drilling will be sent to the laboratory for analysis of recoverable chemical constituents. A proposed list of constituents is provided in Table 1 at the end of this proposal. USGS will coordinate all health and safety issues as well as any necessary permitting.

3. Collect water-quality data from new wells. Sampling and analysis approaches will be tailored to DCDOH needs. It is anticipated that a full suite of constituents, including VOCs, semivolatiles, pesticides, PCBs, total metals, mercury, total cyanide, total phenols, total suspended solids, total dissolved solids, chemical oxygen demand, BOD, oil and grease, TKN, and nutrients will be analyzed. A proposed list of constituents for the initial sampling round (first year of the study) is provided in Table 1 at the end of this proposal.

4. Collect water-level data and determine aquifer properties in new and existing monitoring wells. Water-level data can help determine hydraulic gradients in the aquifer adjacent to the lower Anacostia River. Aquifer tests such as single-well slug tests or multi-well pumping tests can help determine important hydraulic properties of the aquifer. Wells can be instrumented to collect continuous water-level data to help determine the effects of tidal loading on ground-water near the river.

5. Evaluate ground-water contaminant loads to the lower Anacostia River. Estimating ground-water contaminant loads in tidal areas is difficult because of uncertainties inherent in the estimation methods. The best approach in many cases is to use several different methods of data collection and analysis, to synthesize the data into an estimate, and to characterize the uncertainties in the estimate to help resource managers make informed decisions. USGS has pioneered many different methods to obtain data that would be useful for estimating ground-water contaminant loads to the river. For example, chemical analysis of tree-ring cores collected from the shoreline could be used to screen for areas of contaminated ground water near the river. The USGS Hoverprobe could be used to obtain geologic and water-chemistry profiles within the river channel in areas that are inaccessible in any other way. Diffusion samplers could be installed at or near the shoreline as an inexpensive way to sample for volatile organic compounds in ground water, surface water, or the porewater in the sediment beneath the river bottom.

6. Communicate preliminary results and discuss potential new approaches on an ongoing basis throughout the life of the project. USGS understands that priorities sometimes change in a multi-year project, and we usually can adjust to such change. USGS can provide information to DCDOH through periodic progress reports, technical presentations and meetings, data reports, and interpretive reports of various types. As new information or new technologies become available, USGS may propose innovative data collection or analysis methods that could enhance the overall project and add value to the products delivered to DCDOH. Communication throughout.

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