Transport-reaction dynamics of particulate organic matter and oxygen in
riverbed sediments
Abstract
This study deals with the riverbed of the Columbia river in the vicinity
of the Hanford 300 Area study site in eastern Washington, where
fluctuations in river stage take place both naturally (i.e. seasonally)
and in conjunction with hydroelectric power dam operations. These
fluctuations create conditions conducive to the influx and transport of
fine-grained POM (a biological colloid originating from the river water
and/or in situ periphyton production), within near-surface riverbed
sediments. Although a great deal is known about dissolved organic matter
(DOM) transport and metabolism in hyporheic zone sediments, there is a
paucity of quantitative information on POM dynamics and its influence on
hyporheic zone biogeochemistry (e.g. dissolved oxygen dynamics). We have
developed a hydrobiogeochemical model capable of simulating the
transport and metabolism of POM and its impact on dissolved oxygen (DO)
distribution within the riverbed as influenced by periodic changes in
river stage and fluid flow rate and direction. The model was employed as
a tool to interpret the results of in situ measurements of POM intrusion
into the riverbed made using “POM traps” emplaced within the upper 20
cm of the riverbed, as well as real-time in situ dissolved oxygen
concentrations determined with a novel optical sensor buried directly in
the riverbed at 20 cm depth. The simulations reproduced the accumulation
of fresh POM within the upper few 5 cm of the riverbed observed in field
POM trap deployments. Once sufficient surface POM accumulation takes
place, an underlying zone of DO depletion develops as a consequence of
variation in the rate of fluid exchange and POM/DOM degradation. The
model predicted cyclic, hydrologically-driven variations in near-surface
DO that are consistent with the results of the in situ DO probe
deployments together with parallel measurements of fluid conductivity
and hydrologic pressure. Our results suggest a complex interplay between
fluid flow rate/direction and DO distribution that has important
implication for riverbed biogeochemical dynamics at a variety of scales,
as influenced by hydrological variability as well as the relative
intensity of POM input and the availability of oxygen and other electron
acceptors for microbial metabolism.