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Influences of Hydrologic Exchange Flows on River Corridor and Watershed Biogeochemical Function


EMSL Project ID
49749

Abstract

We are developing predictive understanding of the processes that govern influences of hydrologic exchange flows on water quality, nutrient dynamics, and ecosystem health in dynamic river corridor systems. Exchange of water between rivers and the surrounding subsurface environments (hydrologic exchange flows or HEFs) are a vital aspect of watershed function. HEFs lead to enhanced biogeochemical activity (accounting for up to 96% of respiration within river ecosystems) and modulate water temperatures, thus playing a key role in water quality, nutrient dynamics, and ecosystem health. However, these complex processes are not well understood, particularly in the context of large managed rivers with highly variable discharge, and are poorly represented in system-scale quantitative models. Using the 75 km Hanford Reach of the Columbia River as our research domain, we have developed fundamental understanding in several areas including
• Effects of groundwater-surface water mixing on ecological assembly processes, biogeochemical rates, and balance among metabolic pathways
• River water pathways and impacts on contaminant plume mobility
• Physical controls on HEFs at kilometer scales
• Impacts of microbial regulation processes on biogeochemical rates in response to changing environmental conditions
• The nature, speciation, and energetics of organic carbon driving biogeochemical processes.
We are building on this foundation to develop a fundamental and comprehensive scientific understanding of the influences of HEFs (in particular as driven by river discharge variations) on river corridor biogeochemical and ecological functions and to integrate this new-found scientific understanding into a first-of-kind hydrobiogeochemical model of the river corridor, linked as a critical component of watershed systems models. Accordingly, we pursue the resolution of fundamental scientific hypotheses designed to advance understanding of coupled hydrobiogeochemical processes. At the same time, we are developing a hierarchical multiscale modeling framework that will integrate scientific understanding into a predictive watershed modeling capability with wide applicability. New predictive understanding of HEFs and biogeochemistry in the river corridor will play a key role in reduction of uncertainties associated with major Earth system biogeochemical fluxes, improving predictions of environmental and human impacts on water quality and riverine ecosystems, and supporting environmentally responsible management of linked energy-water systems.

Project Details

Start Date
2017-12-01
End Date
2018-09-30
Status
Closed

Team

Principal Investigator

James Stegen
Institution
Pacific Northwest National Laboratory

Co-Investigator(s)

Timothy Scheibe
Institution
Pacific Northwest National Laboratory

Team Members

James Moran
Institution
Michigan State University

Huiying Ren
Institution
Pacific Northwest National Laboratory

Lupita Renteria
Institution
Pacific Northwest National Laboratory

Jacqueline Wells
Institution
Pacific Northwest National Laboratory

Jesus Gomez-Velez
Institution
New Mexico Institute of Mining and Technology

Vanessa Garayburu-Caruso
Institution
Pacific Northwest National Laboratory

Amy Goldman
Institution
Pacific Northwest National Laboratory

Pin Shuai
Institution
Pacific Northwest National Laboratory

Aditi Sengupta
Institution
Pacific Northwest National Laboratory

Emily Graham
Institution
Pacific Northwest National Laboratory

Hyun-Seob Song
Institution
University of Nebraska - Lincoln

Jie Bao
Institution
Pacific Northwest National Laboratory

Xuehang Song
Institution
Pacific Northwest National Laboratory

William Nelson
Institution
Pacific Northwest National Laboratory

Malak Tfaily
Institution
University of Arizona

Xingyuan Chen
Institution
Pacific Northwest National Laboratory

Timothy Johnson
Institution
Pacific Northwest National Laboratory

Zhangshuan Hou
Institution
Pacific Northwest National Laboratory

Maoyi Huang
Institution
Pacific Northwest National Laboratory

Guzel Tartakovsky
Institution
Pacific Northwest National Laboratory

William Perkins
Institution
Pacific Northwest National Laboratory

David Hoyt
Institution
Environmental Molecular Sciences Laboratory

Christopher Strickland
Institution
Washington State University

Thomas Wietsma
Institution
Environmental Molecular Sciences Laboratory

Yilin Fang
Institution
Pacific Northwest National Laboratory

Vicky Freedman
Institution
Pacific Northwest National Laboratory

Glenn Hammond
Institution
Pacific Northwest National Laboratory

James Fredrickson
Institution
Pacific Northwest National Laboratory

Sarah Fansler
Institution
Pacific Northwest National Laboratory

Tom Resch
Institution
Pacific Northwest National Laboratory

Alice Dohnalkova
Institution
Environmental Molecular Sciences Laboratory

John Zachara
Institution
Pacific Northwest National Laboratory

Related Publications

Feng Y., R. Chen, J.C. Stegen, Z. Guo, J. Zhang, Z. Li, and X. Lin. 2018. "Two key features influencing community assembly processes at regional scale: Initial state and degree of change in environmental conditions." Molecular Ecology 27, no. 24:5238-5251. PNNL-SA-129546. doi:10.1111/mec.14914
Stegen J.C., and A.E. Goldman. 2018. "WHONDRS: A community resource for studying dynamic river corridors." mSystems 3, no. 5:Article Number e00151-18. PNNL-SA-136150. doi:10.1128/mSystems.00151-18
Ward A.S., J.P. Zarnetske, V. Baranov, P. Blaen, N. Brekenfeld, R.K. Chu, and R. Derelle, et al. 2019. "Co-located contemporaneous mapping of morphological, hydrological, chemical, and biological conditions in a 5th order mountain stream network, Oregon, USA." Earth System Science Data 11, no. 4:1567-1581. PNNL-SA-140490. doi:10.5194/essd-11-1567-2019
Ward A.S., S.M. Wondzell, N.M. Schmadel, S. Herzog, J.P. Zarnetske, V. Baranov, and P. Blaen, et al. 2019. "Spatial and temporal variation in river corridor exchange across a 5th order mountain stream network." Hydrology and Earth System Sciences 23, no. 12:5199-5225. PNNL-SA-140824. doi:10.5194/hess-23-5199-2019