posted on 2006-03-01, 00:00authored byJie Han, Yan Jin, Clinton S. Willson
Retention and transport of colloids and microorganisms
are complex processes, especially in the vadose zone due
to the more complicated water flow regime and additional
interfacial reactions involved. In this study, we examined
the retention and transport behavior of two bacteriophages,
MS-2 and φX174, in homogeneous and chemically
heterogeneous media under variably saturated conditions.
Column experiments with glass beads (treated to have
either hydrophilic or hydrophobic surface properties) were
conducted using a phosphate-buffered saline solution at
different pore water ionic strengths ranging from 0.025 to
0.163 M. In columns packed with 100% hydrophilic glass
beads, retention of the viruses increased with decreasing
water content and increasing ionic strength, a result
similar to those reported in the literature. However, greater
retention of both MS-2 and φX174 was observed in
saturated columns than in unsaturated columns packed
with a 1:1 mixture of hydrophilic and hydrophobic glass
beads, especially at high ionic strengths. This result
contradicts the common belief that viruses (and colloids
in general) are subject to greater removal in unsaturated
media. Our study suggests that while the mechanisms
controlling colloid interfacial interactions (i.e., attachment
on solid−water and air−water interfaces and film
straining) on the pore scale are relevant, nonuniform
wetting conditions due to heterogeneous grain surface
hydrophobicity can strongly influence water flow and phase
interconnection. Under these conditions, hydrodynamic
effects on the mesopore scale will dominate pore-scale
interfacial reactions in controlling the extent of colloid
retention and movement in unsaturated media.