posted on 2015-04-07, 00:00authored byYouneng Tang, Charles
J. Werth, Robert A. Sanford, Rajveer Singh, Kyle Michelson, Masaru Nobu, Wen-Tso Liu, Albert J. Valocchi
It is widely understood
that selenite can be biologically reduced
to elemental selenium. Limited studies have shown that selenite can
also be immobilized through abiotic precipitation with sulfide, a
product of biological sulfate reduction. We demonstrate that both
pathways significantly contribute to selenite immobilization in a
microfluidic flow cell having a transverse mixing zone between propionate
and selenite that mimics the reaction zone along the margins of a
selenite plume undergoing bioremediation in the presence of background
sulfate. The experiment showed that red particles of amorphous elemental
selenium precipitate on the selenite-rich side of the mixing zone,
while long crystals of selenium sulfides precipitate on the propionate-rich
side of the mixing zone. We developed a continuum-scale reactive transport
model that includes both pathways. The simulated results are consistent
with the experimental results, and indicate that spatial segregation
of the two selenium precipitates is due to the segregation of the
more thermodynamic favorable selenite reduction and the less thermodynamically
favorable sulfate reduction. The improved understanding of selenite
immobilization and the improved model can help to better design in
situ bioremediation processes for groundwater contaminated by selenite
or other contaminants (e.g., uranium(IV)) that can be immobilized
via similar pathways.