Predicting forest carbon content and tree canopy cover on Forest Inventory and Analysis plots along a forest-prairie gradient
2021-12
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Predicting forest carbon content and tree canopy cover on Forest Inventory and Analysis plots along a forest-prairie gradient
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2021-12
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Trees outside forests (TOF) are increasingly recognized as an important resource for carbon storage. TOF include trees used in agricultural windbreaks, urban ornamentals, and trees in non-forest ecosystems like prairie. This study used tree data from the US Forest Service’s Forest Inventory and Analysis (FIA) database to detect variation in forest carbon stocks and tree canopy cover between trees in forest ecosystems and trees in prairie ecosystems. A longitudinal transect was established, extending from Bismarck, ND to Duluth, MN to capture a gradient of mixed temperate forest in the east, prairie in the west, and a transitional zone in the middle. A number of potential transect sizes were evaluated using a series of power analyses (alpha = 0.05, power = 0.88, 0.83) and these determined that a transect radius of 50 km (total transect height 100 km) and transect length of 660 km was sufficient to capture the gradient and provide statistically significant results if differences existed.
All FIA plots within the transect which had tree measurements taken from 2012 – 2018 (n = 4,155) were then used in a series of random forest analyses. The response variables of interest were carbon content (in megagrams per hectare) and percent live canopy cover, both at the plot level. Twenty-seven predictor variables were assessed: a few plot condition indicators from the FIA data, but mostly climate variables (30-year climate normals). Six random forest analyses were run: three examining canopy cover as the response variable using all plots, forest plots, and non-forest plots, and three examining carbon content within the same groupings.
The power analysis lent confidence to the establishment of an effective study area and transect size; however, the random forest analyses were ultimately unable to consistently predict tree canopy cover or carbon content at the plot level. Although the random forest analyses did not provide statistically significant evidence for variation at the plot level, the patterns they revealed between which climate predictors performed best under forested and non-forested conditions are intriguing and may invite further investigation.
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University of Minnesota M.S. thesis. December 2021. Major: Natural Resources Science and Management. Advisor: Matthew Russell. 1 computer file (PDF); v, 28 pages.
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