Viral Transport in a Sand and Gravel Aquifer Under Field Pumping Conditions

Ground water supplies contaminated with microbes cause more than 50% of the water‐borne disease outbreaks in the United States. Proposed regulations suggest natural disinfection as a possible mechanism to treat microbe‐impacted ground water under favorable conditions. However, the usefulness of current models employed to predict viral transport and natural attenuation rates is limited by the absence of field scale calibration data. At a remote floodplain aquifer in western Montana, the bac‐teriophages MS2, φX174, and PRD1; attenuated poliovirus type‐1 (CHAT strain); and bromide were seeded as a slug 21.5 m from a well pumping at a steady rate of 408 L/min. Over the 47‐hour duration of the test, resulting in the exchange of 12 to 13 pore volumes, 77% of the bromide, 55% of the PRD1,17% of the MS2,7% of the φX174, and 0.12% of the poliovirus masses were recovered at the pumping well. Virus transport behavior was controlled by mechanical dispersion, preferential flow, time‐dependent nonreversible and reversible attachment, and apparent mass transfer to immobile domains within the sand and gravel dominated aquifer. The percentage of virus recovery appears correlated with reported viral isoelectric point (pI) values. Successful modeling of viral transport in coarse‐grained aquifers will require separation of viral specific properties from reported lumped viraltransport system parameters.