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A Trial of Fire and Ice: Assessing the Ability of Invasive Tree Pyrus Calleryana to Resist Disturbance During Grassland Invasion in The American MidwestMaloney, Margaret E. 18 May 2021 (has links)
No description available.
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Restoring Degraded and Invaded Landscapes: A Soil-Based ApproachWoods, Michaela J. 15 May 2023 (has links)
No description available.
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Cultivation, overabundance and establishment potential in the emerging invasive <i>Pyrus calleryana</i>HARDIMAN, NICOLE A. 22 September 2008 (has links)
No description available.
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Water Use of Four Commonly Planted Landscape Tree Species in a Semi-Arid Suburban EnvironmentBunnell, Michael Cameron 01 December 2015 (has links)
Native plant communities and agricultural land are commonly converted to urban areas as cities across the Western United States continue to grow and expand. This expansion is typically accompanied by afforestation where a common goal among communities is to maximize shade tree composition. Planted forests in these regions are commonly composed of introduced tree species native to mesic environments and their ability to persist is dependent on consistent irrigation inputs. Many potential ecosystem services may be derived from planting trees in urban and suburban areas; however, there are also costs associated with extensive afforestation, and shade tree cover may have significant implications on municipal water budgets. In this study I evaluate variation in daily and seasonal water use of regionally common suburban landscape tree species in the Heber Valley (Wasatch County, Utah). I had two primary objectives: (1) to identify and understand the differences in transpiration between landscape tree species in a suburban setting and (2) to assess the sensitivity of sap flux and transpiration to variation in vapor pressure deficit, wind speed, and incoming shortwave radiation. I used Granier's thermal dissipation method to measure the temperature difference (ΔT) between two sap flux probes. The empirical equation developed by Granier was used to convert ΔT into sap flux density (Jo) measurements, which were then scaled to whole-tree transpiration. There were consistent and substantial differences in sap flux between tree species. I found that Picea pungens under irrigated growing conditions, on average, had Jo rates that were 32% greater and whole tree water use (ET) rates that were 550% greater than all other species studied. The findings of Jo may be partially explained by xylem architecture and physiological control over stomatal aperture. However, the rate of water flux in the outermost portion of sapwood does not necessarily determine the magnitude of whole tree transpiration. Rather, ET in this study was largely explained by the combined effects of irrigation, tree size, and sapwood to heartwood ratio.
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Invasive plant impacts on recipient community diversity and biomass productionAndrea Nicole Nebhut (13171770) 29 July 2022 (has links)
<p>Biological invasion is a major and growing threat to global biodiversity and human well-being, but research on the impacts of invaders on their recipient environments lags behind that on the mechanisms driving invader establishment and spread. The total impact of an invader is defined by its range size, abundance per unit area, and per-capita effect, with both per-capita effects and abundance varying over time and across the invader’s range. These context-dependencies are determined, in part, by functional differentiation between the invader and its recipient system. In this thesis, I investigate how functional differentiation between invaders and their recipient communities regulates the impact of plant invaders on community diversity and/or biomass production.</p>
<p>First, I compare the effects of invasive Callery pear (<em>Pyrus calleryana</em> Decne.) to functionally similar native trees in three early-successional meadow environments in Indiana’s eastern corn belt plains. Despite my prediction that <em>P. calleryana</em> would have greater negative effects on the total biomass and diversity of the understory plant community compared to native trees, I found that <em>P. calleryana</em> had no significant impact on total cover, species richness, or Shannon’s or Simpson’s diversity indices for the understory community, compared to native <em>Liriodendron tulipifera</em> L., <em>Platanus occidentalis</em> L., or non-tree control plots. Likewise, <em>P. calleryana</em> had no significant impact on the native, introduced, woody, or native tree subsets of the understory community. These results indicate that the trait differences between <em>P. calleryana</em> and functionally similar native trees – and thus the per-invader effect of <em>P. calleryana</em> on its recipient community – are not of a great enough magnitude to produce changes in the understory community composition of these highly invaded, low diversity meadow environments with relatively new and sparse <em>P. calleryana</em> invasions. </p>
<p>I then investigate the role of functional overlap in moderating invader impacts in California serpentine grassland communities through the lens of classic niche theory, which predicts that functional differentiation minimizes competition and therefore allows functionally distinct invaders to achieve higher establishment success but lower per-capita effects on their recipient communities. I tested this prediction by establishing small-scale experimental communities composed of individual or multiple functional groups differentiated by phenology – early-season annuals, nitrogen-fixing early-season annuals, and late-season annuals – and seeding these communities with early- or late-season invaders. I found that as invader density increased, effects on resident community biomass depended on complex patterns of invader and resident functional overlap. Across all resident community functional groups, the high density of early-season invaders enables them to capture a greater portion of total community biomass than late-season invaders, but early-season invaders reduce the ratio of resident:total invader biomass production by less, per-unit-biomass, than late-season invaders. These results highlight the need to consider both niche and fitness differences in predicting invader impacts and the complex nature of resident-invader interactions, which may not be sufficiently captured by coarse functional groups.</p>
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