Changes in groundwater bacterial community during cyclic groundwater-table variations

Column experiments containing an aquifer sand were subjected to static and oscillating water tables to investigate the impact of natural fluctuations and rainfall infiltration on the groundwater bacterial community just below the phreatic surface, and its association with the geochemistry. Once the columns were established, the continuously saturated zone was anoxic in all three columns. The rate of soil organic matter (SOM) mineralization was higher when the water table varied cyclically than when it was static due to the greater availability of NO₃^? and SO₄^2?. Natural fluctuations in the water table resulted in a similar NO₃^? concentration to that observed with a static water table but the cyclic wetting of the intermittently saturated zone resulted in a higher SO₄^2? concentration. Rainfall infiltration induced cyclic water-table variations resulted in a higher NO₃^? concentration than those in the other two columns, and a SO₄^2? concentration intermediate between those columns. As rainwater infiltration resulted in slow downward displacement of the groundwater, it is inferred that NO₃^? and SO₄^2? were being mobilized from the vadose zone. NO₃^? was mainly released by SOM mineralization (which was enhanced by the infiltration of oxygenated rainwater), but the larger amount of SO₄^2? release required a second mechanism (possibly desorption). Different groundwater bacterial communities evolved from initially similar populations due to the different groundwater histories.