When we first created ARTrees, a primary intention was to increase public understanding of trees by reimagining and reexplaining scientific data, literature, and policy. One important bit of science we are particularly interested in dissecting is the valuation of ecosystem services. This concept can be understood as the estimation of services provided by nature in a unit understood by humans: money.
Converting the work of nature into a human currency is a complicated process, so there are a number of methods that have been developed to encompass the wide variety of approaches. One approach has been built into a toolkit called i-Tree. i-Tree includes a suite of tools for measuring various aspects of forest systems, and was developed by the US Forest Service. Of the iTree tools, i-Tree Eco aims to assess the ecosystem services of urban forests, including net storage of carbon, effects of trees on heating and cooling nearby buildings, and removal of urban air pollutants, to name a few.
In 2019, OSU conducted an analysis of campus trees using this tool. Select findings from the report are visualized in ARTrees within the field journal feature, which connects $ values of key services to corresponding trees as users walk throughout campus. The ecosystem services we chose to highlight are structural value, carbon storage, and pollution removal.
Structural value can also be understood as replacement value, because it represents the cost required to replace a tree with one of similar value. Inputs to attain structural values include the type of tree, its diameter and condition, and placement of the tree. These values can be viewed on a forest level or an individual level. In the app, values represent individual-level data. On a forest-level, trends in structural value correspond to the health of the forest. Healthier trees mean greater productivity and higher structural values. In this way, structural value can be viewed as an indicator of forest health.
Carbon storage refers to the net amount of carbon stored in a tree’s branches, trunk, and roots. It is calculated by estimating total biomass of a tree, and adjusting for conditions in which the tree is growing. (E.g. urban trees that are maintained often tend to have lower biomass than trees growing in wild conditions)
One way to understand physical carbon storage quantities is by comparison to major sources of emissions. In comparison to automobile emissions, the amount of carbon stored by OSU trees is equivalent to the annual emissions of 3,040 cars. Annual emissions of a single car were calculated using national averages of vehicle emission rates multiplied by average miles driven per vehicle in 2011, per data by the US EPA and Federal Highway Administration.
In comparison to household emissions, carbon storage by OSU trees was equivalent to the annual emissions of 1,240 single-family homes. Annual emissions of a single household were based on national averages of electricity, natural gas, fuel oil, kerosene, LPG, and wood usages per household in 2009, per data by the Energy Information Administration.
Pollution removal is the ability of trees to cycle air and remove airborne pollutants (such as ozone, sulfur dioxide, and particulate matter 2.5) while doing so. Rates of air pollution removal varies by factors such as leaf area, leaf phenology, and local weather events, all of which must be factored into the model. Interestingly, pollution removal sometimes comes with unexpected effects, including rare cases that generate worse air conditions. For example, it is possible for net removal of PM2.5 to be negative, or for trees to resuspend more particles than they remove, increasing concentrations of pollution. This can occur in droughty conditions, but is rare. Understanding the ways that pollution removal affects the environment is a crucial part of designing a model which reflects the real world as much as possible. Once quantities of removed air pollution are calculated, these values are factored by avoidance costs, or the value of avoiding adverse health effects from polluted air.
The findings explained above represent only a small portion of the conversation surrounding ecosystem services. Researchers are continuously exploring new ways to value these services, and are also often discovering new relationships we engage in as actors within a deeply interconnected system. The results from this field of research have major implications for how we chose to behave in the future. We hope that ARTrees can provide a greater understanding of ecosystem services, and serve as an invitation to further explore.
View the full i-Tree report on OSU trees below: