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Global plant growth not keeping up with CO2 emissions


A recent study published in Nature Climate Change, led by Luc Hoffmann Institute Fellow William Kolby Smith, provides further clues on the interaction between atmospheric carbon and plant growth.

Because plants need carbon dioxide to grow, scientists have expected rising atmospheric CO2 to substantially enhance plant growth, offsetting a portion of human CO2 emissions and, in turn, slowing climate change. However, new research from the Institute on the Environment published in Nature Climate Change adds to a growing body of research challenging this expectation.

The study, led by William Kolby Smith, a Luc Hoffman Institute Fellow working with IonE’s Global Landscapes Initiative and the Natural Capital Project, found that global plant growth has indeed increased over the past 30 years, but not as much as expected given the change in atmospheric CO2 concentrations. Comparing their findings with results of widely used on-the-ground measurements and the best available models of plant responses to increasing CO2, Smith and colleagues concluded that current model estimates of plants’ ability to offset growing greenhouse gas emissions may be unrealistically optimistic.

“Current Earth system models assume that global plant growth will provide the tremendous benefit of offsetting a significant portion of humanity’s CO2 emissions, thus buying us much needed time to curb emissions,” says Smith. “Unfortunately, our observation-based estimates of global vegetation growth indicate that plant growth may not buy us as much time as expected, [so] action to curb emissions is all the more urgent.”

WATER AND NUTRIENTS AVAILABILITY WILL LIMIT PLANT UPTAKE OF CO2

The authors identify two important factors that could be driving the divergence between satellite-based results and model-based results: availability of water and availability of nutrients. Satellite data indicate that warmer climate conditions resulting from rising atmospheric CO2 may be increasing plant water stress, counteracting any positive effect of CO2. Additionally, limited availability of nitrogen and phosphorus in the environment could also limit the ability of plants to soak up additional CO2 (see also previous work co-authored by Smith).

These findings indicate that current climate models do not accurately predict future plant growth and suggest that allowable emissions targets based on these models may need reevaluation. The authors recommend better integration among model, satellite and on-the-ground measurement approaches to improve our understanding of the effects of rising atmospheric CO2 on plant growth.

The work provides an important step forward in the understanding of how plants may respond (or not respond) to rising atmospheric CO2, and it highlights ways in which scientists from different specialties can work together to reach a deeper understanding of how ecosystems will respond to global change, says Sasha Reed, a U.S. Geological Survey scientist and co-author of the paper. “We have many scientific tools in our toolbox, and bringing them together is a powerful approach to asking questions and to solving problems.”

William Kolby Smith is a Luc Hoffman Institute postdoctoral fellow working on the research project Assessing Sustainability Standards. He is based at the University of Minnesota’s Institute of Environment Global Landscapes Initiative and the Natural Capital Project.

Blog post courtesy of University of Minnesota.

Main image: © naturepl.com / Jabruson / WWF

Luc Hoffmann InstituteGlobal plant growth not keeping up with CO2 emissions

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