Improved Understanding of Permafrost Controls on Hydrology in Interior Alaska by Integration of Ground-Based Geophysical Permafrost Characterization and Numerical Modeling

Permafrost and seasonal ground ice are key factors that control the routing of water above and below the land surface in interior Alaska; hence frozen ground affects water resources, ecosystem state, landscape evolution, and soil stability. Despite its hydrologic, ecologic, and geotechnical importan...

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Bibliographic Details
Main Authors: Walvoord, Michelle A, Day-Lewis, Frederick D, Lane, Jr, John W, Striegl, Robert G, Voss, Clifford I, Douglas, Thomas A
Other Authors: ENGINEER RESEARCH AND DEVELOPMENT CENTER FORT RICHARDSON AK COLD REGIONS RESEARCH AND ENGINEERING LAB
Format: Text
Language:English
Published: 2015
Subjects:
Geology
Geochemistry and Mineralogy
Hydrology
Limnology and Potamology
Snow
Ice and Permafrost
*GEOPHYSICS
*HYDROLOGY
*PERMAFROST
ALASKA
DISTRIBUTION
DYNAMICS
FREEZING
GROUND BASED
GROUND WATER
ICE
INTERACTIONS
LAKES
LAYERS
MAPPING
MATHEMATICAL MODELS
MODELS
SIMULATION
SUBARCTIC REGIONS
SURFACE WATERS
THAWING
ACTIVE LAYER
FREEZE THAW DYNAMICS
GROUND ICE
GROUNDWATER MODELING
HYDROLOGIC IMPACTS
INTERIOR ALASKA
TALIKS
YUKON FLATS
GROUNDWATER PERMAFROST INTERACTIONS
PERMAFROST DISTRIBUTION
PERMAFROST-CONTROLLED SURFACE WATER GROUND WATER EXCHANGES
*HYDROLOGIC MODELS
Yukon
Ice
permafrost
Subarctic
Alaska
Online Access:http://www.dtic.mil/docs/citations/ADA621851
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA621851
Description
Summary:Permafrost and seasonal ground ice are key factors that control the routing of water above and below the land surface in interior Alaska; hence frozen ground affects water resources, ecosystem state, landscape evolution, and soil stability. Despite its hydrologic, ecologic, and geotechnical importance, the spatial distribution of permafrost and its relation to subsurface water flow remains poorly understood for many areas of interior Alaska largely due to its remoteness and inaccessibility. This study was aimed at improving the knowledge base by (1) developing a new numerical modeling tool for simulation of groundwater/permafrost interaction; (2) demonstrating and evaluating geophysical methods for mapping of permafrost distribution at several test sites; and (3) elucidating permafrost-controlled surface water/ groundwater exchanges using physics-based modeling to evaluate local settings that were characterized by field efforts and by evaluating larger scale interactions based on generic understanding of permafrost patterns based on geophysical and other data. This research has resulted in both basic-science and methodological advances. The hydrologic modeling tools and approaches and the geophysical methods and evaluation approaches developed here are readily transferrable to a wide range of issues related to permafrost characterization and dynamics affecting cold-region DoD installations and operations. The original document contains color images. Prepared in collaboration with the USGS National Research Program, Central Region, Denver, CO, the USGS Branch of Geophysics, Storrs, CT, and the USGS National Research Program, Western Region, Menlo Park, CA.

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