WRS Masters Defense

Meteorological Variation and Storage Dynamics in Small Peatland Catchments: Marcell Experimental Forest, Minnesota

Using data collected from six headwater peatland catchments at the Marcell Experimental Forest in northern Minnesota, I assessed the relationship between variability in annual precipitation and annual changes in catchment water storage. Three primary questions were addressed; (1) what is the effect of annual and seasonal variability in precipitation on annual water storage change, (2) what is the effect of antecedent annual and seasonal precipitation variability on annual water storage change in subsequent years, and (3) to what extent do wet and dry years influence annual and interannual water storage change. The above relationships were analyzed via cross correlation lag analysis and linear regression analysis of long-term precipitation, peatland water table elevation (WTE), and upland soil moisture (SM) time series, where WTE and SM served to quantify catchment water storage. Results indicate strong correlations between annual water storage change and annual precipitation variability, both in contemporaneous and antecedent years. Concurrent fall precipitation and antecedent winter precipitation were found to have the most influence on a given year’s water storage change. Years in which precipitation fell below the catchment average (dry years) exhibited a moderately significant linear relationship with annual catchment water storage change. Results of the above analysis were used to create a series of multivariate linear regression models, both with and without moving-average (MA) errors; these models were able to explain between approximately 50% and 70% of the variance found in the annual water storage change time series. Boreal peatlands play an important role in the planet’s carbon cycle; developing a better understanding of the hydrologic function of these environments will likely prove important to future climate management practices.