Predicting the Effects of Ozone on Long-Term Growth of Aspen Trees Using Response Functions Developed From Seedlings Grown in Field Chambers

Tropospheric ozone (O3) is among the most pervasive and harmful air pollutants known to affect ecosystems. In the United States, the Environmental Protection Agency and other agencies are tasked with protecting plants and ecosystems from harmful O3 exposures. Controlled exposure experiments conducted in field open-top chambers (OTCs) with small tree seedlings have been used to estimate empirical models of tree growth in response to O3 exposure for more than 16 species. While this experimental method makes it possible to obtain detailed exposure-response data, it remains uncertain whether predictions of empirical models parameterized using those data are sufficiently accurate when applied to trees grown in uncontrolled natural environments for long periods. We used O3 exposure-response relationships developed from several OTC studies of trembling aspen (Populus tremuloides Michx.) seedlings to predict the growth of the same species in the Aspen FACE “free-air” O3 exposure experiment in Rhinelander, Wisconsin, over 11 years. We acquired individual tree growth data and hourly O3 exposure from the ambient and elevated O3 plots in the Aspen FACE experiment, computed annual exposure using the same metrics of O3 exposure as were used in the OTC seedling experiments, and generated predictions of growth in the Aspen FACE exposures. A simple empirical model parameterized using the OTC seedling data accurately predicted the percent above-ground biomass loss due to O3 exposure in the Aspen FACE trees for all 11 years. In the Aspen FACE experiment, the effect of O3 exposure was established in early years and continued to be observed in later years without worsening. Our study suggests that O3 exposure-response relationships obtained from OTC seedling studies can be used to make inferences about effects on larger trees. These results imply that researchers can use these relationships with confidence when estimating risks of O3 pollution across the United States.

Impact/Purpose

Tropospheric ozone is a widespread air pollutant that poses significant risks to plant ecosystems, affecting tree growth and overall forest health. This study assessed the accuracy of models developed from controlled experiments on seedlings to predict the impact of ozone on trees in natural environments. By developing simple statistical models using data from open-top chamber (OTC) experiments and applying these to long-term observations of trembling aspen in the Aspen FACE experiment, we found that these models reliably predicted tree growth loss due to ozone exposure over 11 years. Our study's findings are crucial for understanding how ozone pollution affects forest ecosystems over time and can help guide effective environmental protection strategies. This research is particularly valuable to environmental agencies, forest managers, and policymakers working to mitigate the impacts of air pollution on vegetation and manage forest health.

Citation

Herrick, Jeffrey D., S. Douglas Kaylor, AND Jean-Jacques B. Dubois. Predicting the Effects of Ozone on Long-Term Growth of Aspen Trees Using Response Functions Developed From Seedlings Grown in Field Chambers. Blackwell Publishing, Malden, MA, 30(12):e70003, (2024). [DOI: 10.1111/gcb.70003]

DOI: Predicting the Effects of Ozone on Long-Term Growth of Aspen Trees Using Response Functions Developed From Seedlings Grown in Field Chambers