Characterization of Boreal-Arctic Vegetation Growth Phases and Active Soil Layer Dynamics in the High-Latitudes of North America: A Study Combining Multi-Year In Situ and Satellite-Based Observations
This dissertation examined the seasonal freeze/thaw activity in boreal-Arctic soils and vegetation physiology in Alaska, USA and Alberta, Canada, using in situ environmental measurements and passive microwave satellite observations. The boreal-Arctic high-latitudes have been experiencing ecosystem c...
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| Format: | Doctoral or Postdoctoral Thesis |
| Language: | English |
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CUNY Academic Works
2023
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| Online Access: | https://academicworks.cuny.edu/gc_etds/5260 https://academicworks.cuny.edu/cgi/viewcontent.cgi?article=6364&context=gc_etds |
| Summary: | This dissertation examined the seasonal freeze/thaw activity in boreal-Arctic soils and vegetation physiology in Alaska, USA and Alberta, Canada, using in situ environmental measurements and passive microwave satellite observations. The boreal-Arctic high-latitudes have been experiencing ecosystem changes more rapidly in comparison to the rest of Earth due to the presently warming climatic conditions having a magnified effect over Polar Regions. Currently, the boreal-Arctic is a carbon sink; however, recent studies indicate a shift over the next century to become a carbon source. High-latitude vegetation and cold soil dynamics are influenced by climatic shifts and are largely responsible for the regions atmospheric carbon fluxes. Under a warming climate, soils are thawing for extended periods of time, allowing for heightened aerobic decomposition of organic matter in the soil, increasing soil carbon emissions. Simultaneously, vegetation performs photosynthesis longer, resulting in increased sequestering of atmospheric carbon. Regional and global climate affect one another through land-atmosphere carbon feedbacks. The strength, and contribution, of this study lies in high quality fine-scale in situ datasets day-of-year occurrences for soil state transitions and vegetation growth phenophase activity at site-specific locations. Findings include (1) a more thermally variable active layer in dry tundra compared to wet tundra; (2) active layer isothermal conditions are established rapidly in the fall ( ~ 2 days) but not in the spring (~ 11 days); (3) boreal willow shrubs (Salix Spp.) have the shortest exiting dormancy period (11 days) yet the longest active above ground stem growth (61 days); (4) moist bog type environments were shown to be the optimal spruce (Picea Spp.) growth environments (active trunk growth duration of ~ 55 days); and (5) AMSR satellite data were shown to preemptively estimate land surface condition change compared to in-situ measurements during the spring transition for both tundra types while ... |
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