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Observing Semi-Arid Ecoclimates across Mountain Gradients in the Great Basin, USA
Date
2016Type
DissertationDepartment
Geography
Degree Level
Doctorate Degree
Abstract
Observation of climate and ecohydrological variables in mountain systems is a necessary (if challenging) endeavor for modern society. Water resources are often intimately tied to mountains, and high elevation environments are frequently home to unique landscapes and biota with limited geographical distributions. This is especially true in the temperate and semi-arid mountains of the western United States, and specifically the Great Basin. Stark contrasts in annual water balance and ecological populations are visible across steep elevational gradients in the region; and yet the bulk of our historical knowledge of climate and related processes comes from lowland observations. Interpolative models that strive to estimate conditions in mountains using existing datasets are often found to be inaccurate, making future projections of mountain climate and ecosystem response suspect. This study details the results of high-resolution topographically-diverse ecohydrological monitoring, and describes the character and seasonality of basic climatic variables such as temperature and precipitation as well as their impact on soil moisture and vegetation during the 2012-2015 drought sequence. Relationships of topography (elevation/aspect) to daily and seasonal temperatures are shown. Tests of the PRISM temperature model are performed at the large watershed scale, revealing magnitudes, modes, and potential sources of bias that could dramatically affect derivative scientific conclusions. A new method of precipitation phase partitioning to detect and quantify frozen precipitation on a sub-daily basis is described. Character of precipitation from sub-daily to annual scales is quantified across all major Great Basin vegetation/elevation zones, and the relationship of elevation to precipitation phase, intensity, and amount is explored. Water-stress responses of Great Basin conifers including Pinus flexilis, Pinus longaeva, and Pinus ponderosa are directly observed, showing potential differences in drought adaptation. Overall results highlight the seasonal flexibility of semi-arid conifer water use, as well as the tendency of topoclimate to buffer mountain ecosystems from extreme seasonal events. Methods and practices used in this study are globally applicable to mountain observatory efforts; especially the themes of topographic diversity, siting design, and leverage of technology and cyberinfrastructure.
Permanent link
http://hdl.handle.net/11714/2229Additional Information
Committee Member | Millar, Constance; Charlet, David; Tausch, Robin; McAfee, Stephanie |
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Rights | In Copyright(All Rights Reserved) |
Rights Holder | Author(s) |