Your search keyword '"Christopher A. Lowry"' showing total 7 results

1. Limits on Groundwater‐Surface Water Fluxes Derived from Temperature Time Series: Defining Resolution‐Based Thresholds

Author

Mark B. Hausner, Christopher S. Lowry, and Thomas J. Glose

Subjects

Series (mathematics), Resolution (electron density), Environmental science, Soil science, Surface water, Groundwater, Water Science and Technology

Published

2019

2. Improving Hydrological Models With the Assimilation of Crowdsourced Data

Author

Pedro Avellaneda, Darren L. Ficklin, Christopher S. Lowry, Jason H. Knouft, and Damon M. Hall

Subjects

Data assimilation, Meteorology, Streamflow, Citizen science, Environmental science, Assimilation (biology), Stream temperature, Water Science and Technology

Published

2020

3. Response of the hyporheic zone to transient groundwater fluctuations on the annual and storm event time scales

Author

Jonathan M. Malzone, Christopher S. Lowry, and Adam S. Ward

Subjects

Hydrology, Biogeochemical cycle, geography, geography.geographical_feature_category, Water table, 0208 environmental biotechnology, Storm, 02 engineering and technology, Stream metabolism, 020801 environmental engineering, Environmental science, Hyporheic zone, Surface water, Groundwater, Water Science and Technology, Riparian zone

Abstract

The volume of the water stored in and exchanged with the hyporheic zone is an important factor in stream metabolism and biogeochemical cycling. Previous studies have identified groundwater direction and magnitude as one key control on the volume of the hyporheic zone, suggesting that fluctuation in the riparian water table could induce large changes under certain seasonal conditions. In this study, we analyze the transient drivers that control the volume of the hyporheic zone by coupling the Brinkman-Darcy equation to the Navier-Stokes equations to simulate annual and storm induced groundwater fluctuations. The expansion and contraction of the hyporheic zone was quantified based on temporally dynamic scenarios simulating annual groundwater fluctuations in a humid temperate climate. The amplitude of the groundwater signal was varied between scenarios to represent a range of annual hydrologic forcing. Storm scenarios were then superimposed on the annual scenario to simulate the response to short-term storm signals. Simulations used two different groundwater storm responses; one in-phase with the surface water response and one 14 h out-of-phase with the surface water response to represent our observed site conditions. Results show that annual groundwater fluctuation is a dominant control on the volume of the hyporheic zone, where increasing groundwater fluctuation increases the amount of annual variation. Storm responses depended on the antecedent conditions determined by annual scenarios, where the time of year dictated the duration and magnitude of the storm induced response of the hyporheic zone.

Published

2016

4. Hyporheic exchange controlled by dynamic hydrologic boundary conditions

Author

Adam S. Ward, Christopher S. Lowry, Noah M. Schmadel, and Jonathan M. Malzone

Subjects

Hydrology, Geophysics, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, General Earth and Planetary Sciences, Environmental science, 02 engineering and technology, Boundary value problem, 01 natural sciences, Flux (metabolism), 020801 environmental engineering, 0105 earth and related environmental sciences

Published

2016

5. Groundwater controls on vegetation composition and patterning in mountain meadows

Author

Courtney E. Moore, Christopher S. Lowry, Jessica D. Lundquist, and Steven P. Loheide

Subjects

Hydrology, geography, Watershed, geography.geographical_feature_category, Groundwater flow, Water table, Snowmelt, Environmental science, DNS root zone, Land cover, Groundwater, Water Science and Technology, Riparian zone

Abstract

[1] Mountain meadows are groundwater-dependent ecosystems that are hot spots of biodiversity and productivity. In the Sierra Nevada mountains of California, these ecosystems rely on shallow groundwater to support their vegetation communities during the dry summer growing season in the region's Mediterranean montane climate. Vegetation composition in this environment is influenced by both (1) oxygen stress that occurs when portions of the root zone are saturated and anaerobic conditions limit root respiration and (2) water stress that occurs when the water table drops and the root zone becomes water limited. A spatially distributed watershed model that explicitly accounts for snowmelt processes was linked to a fine-resolution groundwater flow model of Tuolumne Meadows in Yosemite National Park, California, to simulate water table dynamics. This linked hydrologic model was calibrated to observations from a well observation network for 2006–2009. A vegetation survey was also conducted at the site in which the three dominant species were identified at more than 200 plots distributed across the meadow. Nonparametric multiplicative regression was performed to create and select the best models for predicting vegetation dominance on the basis of the simulated hydrologic regime. The hydrologic niches of three vegetation types representing wet, moist, and dry meadow vegetation communities were found to be best described using both (1) a sum exceedance value calculated as the integral of water table position above a depth threshold of oxygen stress and (2) a sum exceedance value calculated as the integral of water table position below a depth threshold of water stress. This linked hydrologic and vegetative modeling framework advances our ability to predict the propagation of human-induced climatic and land use or land cover changes through the hydrologic system to the ecosystem. The hydroecologic functioning of meadows provides an example of the extent to which cascading hydrologic processes at watershed, hillslope, and riparian zones and within channels are reflected in the composition and distribution of riparian vegetation.

Published

2011

6. Groundwater-dependent vegetation: Quantifying the groundwater subsidy

Author

Steven P. Loheide and Christopher S. Lowry

Subjects

Hydrology, geography, geography.geographical_feature_category, Water table, Soil science, Groundwater recharge, Water resources, Soil water, Environmental science, Water content, Groundwater, Water Science and Technology, Waterlogging (agriculture), Riparian zone

Abstract

[1] The typical stratigraphy of riparian ecosystems consists of fine-grained overbank deposits overlying coarser-grained materials. Plants within these regions rely on soil moisture in the fine-grained sediments as well as supplemental groundwater for root water uptake. The additional water available as a result of shallow water table conditions is defined here as groundwater subsidy and is found to be a significant contribution to root water uptake. Work presented here quantifies the effect of groundwater subsidy on root water uptake as a result of variations in the soil thickness of the upper fine-grained sediments, rate of water table decline, and maximum water table depth. Variations in soil thickness and water table decline regimes produce a complex response with respect to both the rate of groundwater subsidy and the cumulative groundwater subsidy. These simulated regimes are analogs to environmental scenarios in riparian ecosystems that result from stream incision, soil erosion, and climate change. These results have implications for identifying ecosystems most susceptible to future change as well as those most amenable to restoration.

Published

2010

7. Identifying spatial variability of groundwater discharge in a wetland stream using a distributed temperature sensor

Author

John F. Walker, Randall J. Hunt, Mary P. Anderson, and Christopher S. Lowry

Subjects

Hydrology, geography, geography.geographical_feature_category, Water dynamics, Peat, Environmental science, Groundwater discharge, Spatial variability, Wetland, STREAMS, Surface water, Water Science and Technology

Abstract

[1] Discrete zones of groundwater discharge in a stream within a peat-dominated wetland were identified on the basis of variations in streambed temperature using a distributed temperature sensor (DTS). The DTS gives measurements of the spatial (±1 m) and temporal (15 min) variation of streambed temperature over a much larger reach of stream (>800 m) than previous methods. Isolated temperature anomalies observed along the stream correspond to focused groundwater discharge zones likely caused by soil pipes within the peat. The DTS also recorded variations in the number of temperature anomalies, where higher numbers correlated well with a gaining reach identified by stream gauging. Focused zones of groundwater discharge showed essentially no change in position over successive measurement periods. Results suggest DTS measurements will complement other techniques (e.g., seepage meters and stream gauging) and help further improve our understanding of groundwater-surface water dynamics in wetland streams.

Published

2007