Pacific Northwest National Laboratory staff collects ground water samples along the Hanford Reach shoreline using small-diameter polyethylene tubing that is implanted into the cobbly sediment. Water samples are periodically withdrawn to monitor the characteristics of ground water that discharges into the river through the riverbed.

"Leave No Trace" is a popular ethic for outdoor recreationists who advocate a natural landscape. Now also it is applicable to ground water sampling collection sites along the Columbia River in southeastern Washington State.

Hydrologists from the Department of Energy's Pacific Northwest National Laboratory are using a simple apparatus of 1/4-inch-diameter plastic tubing to collect samples at varying levels in the aquifer along the river's edge. Though a permanent installation, the low-cost, lightweight materials are easy to camouflage with indigenous rocks and vegetation so that the collection site appears undisturbed.

Hydrologists compare the aquifer tube method to sipping ground water through a long straw. The tube system was developed to provide supplemental monitoring in locations where traditional monitoring wells cannot be installed because of access constraints. It has proven to be economical, visually unobtrusive and effective in providing an accurate picture of the vertical distribution of contaminants in ground water at a specific location.

To install the tubes, a handheld air hammer is used to drive a temporary steel casing into the ground. Plastic tubing is lowered into the casing. Typically, three tubes are installed at each location, reaching depths of approximately 25, 15 and 6 feet. The bottom 6 inches of tubing is screened with stainless steel mesh and provides an opening for drawing water samples. After the tubes are anchored in place, the casing is removed, leaving a short section of tubing extending out of the ground. Suction from a handheld peristaltic pump slowly withdraws water from the tubes. When the tubes are not in use, the top ends are capped and covered with PVC pipe to protect them from weather, animals and other hazards, and camouflaged with natural materials to blend in with the environment.

The Hanford Site Environmental Restoration Contractor team, with encouragement from the Department of Energy, conceived the tube design in 1995 as a way to expand ground water monitoring. The Hanford Site produced plutonium for defense during and after World War II and is the scene of the world's largest environmental cleanup project.

The tubes are installed and sampled with hand-held equipment carried to the sites by boat to ensure little disturbance to the environment.

Site contractors equipped additional sites along the river with the samplers in 1997 and 2004. Today coverage includes 320 tubes located at 132 sites situated approximately half-mile apart along a 26-mile stretch of shoreline.

"Being able to monitor ground water where we couldn't put traditional wells has been a real benefit," says PNNL geologist Bob Peterson. "And being able to do it while leaving an area essentially untouched makes the sampling tubes an even better idea."

The tubes provide the ability to get an accurate picture of the vertical distribution of contaminants in ground water at a specific location. The three tubes typically installed at each location vary in length, enabling the ports at the end of each tube to monitor three discreet depths in the aquifer.

The monitoring methodology has a wide variety of potential applications at sites other than Hanford, Peterson says. The simple equipment and installation logistics mean the aquifer tubes can be employed almost anywhere there is a need to monitor shallow ground water systems or the saturated sediment zone associated with surface water bodies.

For example, the tubes could be used to monitor subsurface discharge from agricultural areas, river bottom subsurface habitat, estuary health, CERCLA site remedial investigations and EPA total maximum daily load of ground water influx to streams and lakes, Peterson says. Installations also can be adapted to incorporate in-situ instrumentation for continuous monitoring of conditions.
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