Long-term Managed Flooding to Control Invasive Phalaris Arundinacea L. and Help Restore Native Vegetation in an Urban Palustrine Wetlands Ecosystem
Long-term Managed Flooding to Control Invasive Phalaris Arundinacea L. and Help Restore Native Vegetation in an Urban Palustrine Wetlands Ecosystem

Author:

Publisher:

Published: 2018

Total Pages: 90

ISBN-13:

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We sought to determine the effects of 13 years of hydrologic management on the wetland plant community in Smith and Bybee Wetlands Natural Area (SBW), an 809 ha palustrine wetland complex in north Portland, Oregon. Previous management efforts resulted in an altered hydrologic regime; historically high water levels in spring and low water levels in fall were replaced by persistent water levels with minimal annual variations. A water control structure was installed in 2003 to better approximate historic seasonal hydrologic changes to reduce invasive Phalaris arundinacea (reed canarygrass) cover and promote native wetland vegetation growth. Vegetation monitoring has been carried out in three phases since project initiation (2003-2004, 2008-2009, and 2015-2016) to assess restoration efforts. Using lineintercept and differential leveling methods, we measured 25 randomly established transects ranging from 21.5m to 280.7m (mean: 92.87m) during monitoring years for vegetation and elevation to determine changes in vegetation in relation to seasonally varying water levels. Overall, reed canarygrass percent cover has decreased from 46.5% in 2003 to 17.6% in 2016 across all transect elevations. Reed canarygrass has been replaced significantly by seven native plant species with ≥ 5% cover on site. Native Persicaria amphibia (smartweed) has replaced reed canarygrass as the dominant species on site, increasing in cover from 20.2% in 2003 to 67.9% in 2016. Smartweed also replaced all other common species on site except for Salix lucida lasiandra. Other common native species (Bidens cernua, Eragrostis hypnoides, Eleocharis palustris, and Cyperus sp.) experienced earlier declines in cover between 2003 and 2009, but have since increased in cover primarily in low transect elevations in relation to lower inundation rates during their early growing seasons. Species diversity has declined significantly since 2003. Diversity was inversly correlated with reed canarygrass presence in 2003. These findings demonstrate that hydrologic management of a wetland system can be effective at reducing the presence of reed canarygrass and increasing native wetland vegetation by recreating historic hydrologic conditions that include increased inundation during the early growing season of reed canarygrass. Initial long inundation periods were most effective at reducing reed canarygrass, but did not need to be maintained indefinitely. Shortening and varying the inundation periods in later years after reed canarygrass has been reduced can be effective at maintaining lower levels of reed canarygrass while simultaneously increasing native species cover.

Ecohydrology Effects of an Invasive Grass (Phalaris Arundinacea) on Semi-arid Riparian Zones
Ecohydrology Effects of an Invasive Grass (Phalaris Arundinacea) on Semi-arid Riparian Zones

Author: Adam D. Gebauer

Publisher:

Published: 2013

Total Pages: 138

ISBN-13:

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"Riparian areas (floodplains) provide key ecological functions that are linked to the ecohydrology however; they are particularly susceptible to invasion by alien species. In much of the western United States, riparian zones are shifting from native woody and herbaceous species to invasive grass dominated ecosystems that may alter hydrology, including changes to stream flow. Compared to the woody species they often replace, dense grass stands may have higher rates of growth (productivity) and water loss through leaves (transpiration), yet may access shallower water sources and thus reduce stream flow. In eastern Washington, many streams experience low flow that degrades water quality, concentrates pollutants, and reduces habitat. Most of these streams' riparian zones have extensive stands of reed canary grass (Phalaris arundinacea). Reed canary grass was historically planted for erosion control and as a forage crop, but its ability to invade and create monotypic stands has allowed it to out compete native vegetation in riparian areas throughout much of the temperate United States. My goal is to determine the effect of reed canary grass on the ecohydrology of riparian zones along low order streams in a semi-arid region. I conducted vegetation, groundwater, and stream flow surveys at nine sites along four watersheds to determine community composition and hydrologic regime measured the length of the growing season for nine riparian species. I measured the amount of biomass and calculated the amount of photosynthetic surface for dense stands of nine riparian species. The amount of water used by different species was determined by measuring transpiration rates of reed canary grass and other riparian species throughout the growing season. Hydrogen and oxygen isotopes from different water sources (stream water and deep groundwater) were used to determine the proportion of water sources use by different plants species. Reed canary grass was found with greater cover than other riparian species on low elevation geomorphic positions in the riparian zone. It had the longest growing season by two weeks. Although its transpiration rates per unit leaf area are not exceptional compared to other species, its high specific leaf area and ability to produce dense stands of photosynthetic biomass results in more photosynthetic surface through which to transpire water than any other riparian species. Reed canary grass was found to rely heavily on surface water sources along different elevations in the riparian zone. My results implicate reed canary grass as a major factor in the regional low stream flow during the growing season. Although the presence of reed canary grass can add some benefits to a riparia buffer, I present strong evidence that it is altering the ecohydrology of these ecosystems. The management of this grass, particularly in a semi-arid region, could improve water quality and quantity"--Document.

Plant and Macroinvertebrate Responses to Water Regime in a Whitetop Marsh
Plant and Macroinvertebrate Responses to Water Regime in a Whitetop Marsh

Author: Hilary Alison Neckles

Publisher:

Published: 1984

Total Pages: 109

ISBN-13:

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This study examined the role of water regime in the ecology of seasonally flooded prairie wetlands, and the potential for using water level manipulation as a seasonal marsh management tool. Specific objectives were 1) to determine the effects of water regime on decomposition of whitetop (Scolochloa festucacea), a dominant emergent grass of seasonal prairie wetlands, 2) to determine the influence of water regime on macroinvertebrate abundance in seasonal marshes, and 3)to compare whitetop forage yield under dry and seasonally flooded conditions. Distinct water regimes (permanent drought, permanent flooding, or seasonal flooding) were applied to 3 contiguous impoundments on the Delta Marsh, Manitoba, from April 1981 through July 1983. Responses within the litter, aquatic macroinvertebrate, and aboveground macrophyte components to each treatment were measured.Prolonged flooding hastened weight loss from whitetop litter.Differences in weight loss patterns were related to the length of.