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dc.contributor.advisorIreson, Andrew M.
dc.creatorNazarbakhsh, Mahtab 1988-
dc.date.accessioned2019-03-28T20:02:47Z
dc.date.available2019-03-28T20:02:47Z
dc.date.created2019-03
dc.date.issued2019-03-28
dc.date.submittedMarch 2019
dc.identifier.urihttp://hdl.handle.net/10388/11933
dc.description.abstractThe exchanges of water energy and carbon between the land surface and the atmosphere are tightly coupled, so that errors in simulating evapotranspiration will lead to errors in simulating the water, carbon and energy cycles. This will impair water resource evaluations and numerical weather predictions. Currently, land surface schemes have shown deficiencies in the simulation of evapotranspiration at the southern edge of the boreal forest in Saskatchewan, Canada. The purpose of this research is to improve the understanding of controls on evapotranspiration from forest canopies in regions with seasonally frozen soils, by critically examining field observations and outputs from state–of–the–art models. Simulated evapotranspiration is sensitive to soil and vegetation properties, which are variable in time and space and therefore introduce large uncertainties. Seasonally frozen soils present a particular challenge due to their snowmelt–dominated hydrology and the impact of soil freezing on the soil hydraulic properties and plant root water uptake. This thesis critically assesses the performance of the Canadian Land Surface Scheme (CLASS) and the coupled Canadian Land Surface Scheme and Canadian Terrestrial Ecosystem Model (CLASS–CTEM) for simulating point–scale evapotranspiration at a mature jack pine site located at the southern edge of the boreal forest in Saskatchewan, Canada. Past models applied to this site have consistently over–predicted evapotranspiration, particularly in the period following snowmelt. This research applies sensitivity analysis to explore how evapotranspiration is controlled by soil hydraulic and plant properties (soil water retention and conductivity, root depth/distribution, leaf area index, and the canopy conductance model), with special focus on the spring melt period when transpiration commences. This investigation found that errors in the soil hydraulic properties, root distribution, or leaf area index could not individually explain the model errors although these properties do all have important impacts on the water balance. The parameterization of canopy conductance could potentially explain the model errors. Although canopy conductance and leaf area index are dependent, the bias in simulation of evapotranspiration cannot be explained by the errors in leaf area index – given the fact that at this site we have site specific estimates of leaf area index. Errors in the simulation of evapotranspiration were greatest during and just after the soil–thaw period in spring. It is recommended, therefore, to further investigate the simulation of evapotranspiration from frozen soils.
dc.format.mimetypeapplication/pdf
dc.subjectLand Surface Schemes
dc.subjectSeasonally Frozen Soils
dc.subjectEvapotranspiration
dc.subjectSnowmelt
dc.subjectSoil Hydraulic Properties
dc.subjectVegetation Characteristics
dc.subjectEco-hydrology
dc.subjectBoreal Forest
dc.titleUnderstanding controls on springtime evapotranspiration from jack pine (Pinus Banksiana) forest with seasonally frozen soils
dc.typeThesis
dc.date.updated2019-03-28T20:02:47Z
thesis.degree.departmentSchool of Environment and Sustainability
thesis.degree.disciplineEnvironment and Sustainability
thesis.degree.grantorUniversity of Saskatchewan
thesis.degree.levelMasters
thesis.degree.nameMaster of Environment and Sustainability (M.E.S.)
dc.type.materialtext
dc.contributor.committeeMemberBarr, Alan G.
dc.contributor.committeeMemberLaroque, Colin
dc.contributor.committeeMemberWestbrook , Cherie
dc.creator.orcid0000-0002-0410-0426


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