EFFECTS OF HYDROLOGIC CONNECTIVITY ON WATER CHEMISTRY, SOILS, AND VEGETATION STRUCTURE AND FUNCTION IN AN INTERMONTANE DEPRESSIONAL WETLAND LANDSCAPE

EFFECTS OF HYDROLOGIC CONNECTIVITY ON WATER CHEMISTRY, SOILS, AND VEGETATION STRUCTURE AND FUNCTION IN AN INTERMONTANE DEPRESSIONAL WETLAND LANDSCAPE

Historically, depressional wetlands have been viewed as small, closed basins without a naturally integrated inter-wetland surface drainage system. In this view, landscape-level connectivity is limited to surface water as overland flow. Contrasting with this view, conceptual prairie pothole ground-wa...

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Bibliographic Details
Published in:Wetlands (Wilmington, N.C.) Vol. 27; no. 3; pp. 719 - 738
Main Authors: Cook, Bradley J., Richard Hauer, F.
Format: Journal Article
Language:English
Published: 1313 Dolley Madison Boulevard, Suite 402, McLean, Virginia, USA 22101 The Society of Wetland Scientists 01-09-2007
Springer Nature B.V
Subjects:
Catchments
Community composition
Community structure
Connectivity
Drainage systems
Fluid dynamics
Freshwater
Geomorphology
ground water hydrology
Groundwater
groundwater connectivity
groundwater discharge
groundwater flow
hydrochemistry
hydrogeology
Hydrology
isolated wetlands
Landscape
Moisture content
Net Primary Productivity
Overland flow
Physical simulation
Plant communities
Potholes
prairie pothole
prairies
Productivity
REGULAR SUBMISSIONS
Soil chemistry
Soil moisture
Soil structure
Soil surfaces
Soil water
soil water movement
Soil water storage
Solutes
Structural basins
Structure-function relationships
Surface drainage
Surface runoff
Surface water
Vegetation
vegetation structure
Water chemistry
Water exchange
wetland ecology
wetland hydrology
wetland plants
wetland soils
Wetlands
Montana
Prairie Pothole region
USA, Montana
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Summary:Historically, depressional wetlands have been viewed as small, closed basins without a naturally integrated inter-wetland surface drainage system. In this view, landscape-level connectivity is limited to surface water as overland flow. Contrasting with this view, conceptual prairie pothole ground-water models have relied on ground-water connectivity to explain inter-wetland differences in salinity, duration of inundation, and vegetation structure. To help clarify this contrast, we compared differences in hydrology, ground-water connectivity, near-surface soil moisture, geomorphology, water chemistry, and vegetation community structure and productivity for a suite of depressional wetlands in an intermontane prairie of western Montana. We compared depressional wetlands with and without temporary (< 4 wk) surface-water and/or soil-water connections. Connected wetlands had significantly smaller catchments, but stored more water, stored water longer, and had higher specific conductance than did isolated wetlands. Connected wetlands also had higher net primary productivity and a different plant community composition than did isolated wetlands. Comparisons of study site hydrology, water chemistry, and soil development found strong evidence for no ground-water exchange among any of the wetlands. The absence of ground water connection among these intermontane depressional wetlands emphasizes the importance of temporary surface-water and soil-water connections in depressional wetland ecology, as well as the need to understand the landscape scale variation of dissolved solutes and the distribution, abundance, and productivity of wetland plants among depressional wetlands and across wetland landscapes.
Bibliography:http://dx.doi.org/10.1672/0277-5212(2007)27[719:EOHCOW]2.0.CO;2
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0277-5212
1943-6246
DOI:10.1672/0277-5212(2007)27[719:EOHCOW]2.0.CO;2