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Complexity in river-groundwater exchange due to permeability heterogeneity, in-stream flow obstacles, and river stage fluctuationsSawyer, Audrey Hucks 13 July 2011 (has links)
River-groundwater exchange (hyporheic exchange) influences temperature, water
chemistry, and ecology within rivers and alluvial aquifers. Rates and patterns of
hyporheic exchange depend on riverbed permeability, pressure gradients created by
current-obstacle interactions, and river stage fluctuations. I demonstrate the response of
hyporheic exchange to three examples of these driving forces: fine-scale permeability
structure in cross-bedded sediment, current interactions with large woody debris (LWD),
and anthropogenic river stage fluctuations downstream of dams.
Using numerical simulations, I show that cross-bedded permeability structure
increases hyporheic path lengths and modifies solute residence times in bedforms. The
tails of residence time distributions conform to a power law in both cross-bedded and
internally homogeneous riverbed sediment. Current-bedform interactions are responsible
for the decade-scale tails, rather than permeability heterogeneity.
Like bedforms, wood debris interacts with currents and drives hyporheic exchange. Laboratory flume experiments and numerical simulations demonstrate that the
amplitude of the pressure wave (and thus hyporheic exchange) due to a channel-spanning log increases with channel Froude number and blockage ratio (log diameter : flow depth).
Upstream from LWD, downwelling water transports the river’s diel thermal signal deep into the sediment. Downstream, upwelling water forms a wedge of buffered
temperatures. Hyporheic exchange associated with LWD does not significantly impact diel surface water temperatures. I tested these fluid and heat flow relationships in a second-order stream in Valles Caldera National Preserve (NM). Log additions created alternating zones of upwelling and downwelling in a reach that was previously losing throughout. By clearing LWD from channels, humans have reduced hydrologic connectivity at the meter-scale and contributed to degradation of benthic and hyporheic habitats.
Dams also significantly alter hydrologic connectivity in modern rivers. Continuous water table measurements show that 15 km downstream of the Longhorn dam
(Austin, Texas), river stage fluctuations of almost 1 m induce a large, unsteady hyporheic
exchange zone within the bank. Dam-induced hyporheic exchange may impact thermal and geochemical budgets for regulated rivers. Together, these three case studies broaden our understanding of complex drivers of hyporheic exchange in small, natural streams as well as large, regulated rivers. / text
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Flow, nutrient, and stable isotope dynamics of groundwater in the parafluvial/hyporheic zone of a regulated river during a small pulseBriody, Alyse Colleen 27 October 2014 (has links)
Periodic releases from an upstream dam cause rapid stage fluctuations in the Colorado River near Austin, Texas. These daily pulses modulate fluid exchange and residence times in the hyporheic region, where biogeochemical reactions are pronounced. We installed two transects of wells perpendicular to the river to examine in detail the reactions occurring in this zone of surface-water and groundwater exchange. One well transect recorded physical water level fluctuations and allowed us to map hydraulic head gradients and fluid movement. The second transect allowed for water sample collection at three discrete depths. Samples were collected from 12 wells every 2 hours for a 24-hour period and were analyzed for nutrients, carbon, major ions, and stable isotopes. The results provide a detailed picture of biogeochemical processes in the bank environment during low flow/drought conditions in a regulated river. Findings indicate that a pulse that causes a change in river stage of approximately 16-centimeters does not cause significant mixing in the bank. Under these conditions, the two systems act independently and exhibit only slight mixing at the interface. / text
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