Plants Are Taking in 31% More Carbon Dioxide Than We Previously Believed

by Anna

Recent research published in Nature reveals that plants worldwide absorb approximately 31% more carbon dioxide (CO2) than previously estimated. This significant finding, developed by scientists from Cornell University and the Department of Energy’s Oak Ridge National Laboratory, underscores the vital role of natural carbon sequestration in mitigating greenhouse gas emissions and enhancing climate predictions.

Understanding Terrestrial Gross Primary Production (GPP)

The Terrestrial Gross Primary Production (GPP) refers to the amount of CO2 that land plants remove from the atmosphere through photosynthesis. This process represents the largest carbon exchange between land and the atmosphere globally. GPP is typically measured in petagrams of carbon per year, where one petagram equals 1 billion metric tons—a volume comparable to the annual emissions from about 238 million gas-powered vehicles.

New Findings on GPP

The research team revised the GPP estimate to 157 petagrams of carbon per year, a significant increase from the previous estimate of 120 petagrams established four decades ago. The study is encapsulated in the paper titled “Terrestrial Photosynthesis Inferred from Plant Carbonyl Sulfide Uptake.”

Methodology: Using Carbonyl Sulfide as a Proxy

The scientists developed an innovative model that tracks the movement of carbonyl sulfide (OCS) from the air into leaf chloroplasts, where photosynthesis occurs. OCS serves as a photosynthesis proxy because it closely mimics the path of CO2 but is easier to measure. This allows for a reliable estimation of GPP at large scales and over extended periods, making OCS a valuable tool in understanding global photosynthetic activity.

Integrating Data Sources

To develop the model, the research team utilized plant data from various sources, including the LeafWeb database from ORNL, which collects global photosynthetic traits data to support carbon cycle modeling. The model’s accuracy was verified using high-resolution data from environmental monitoring towers rather than relying solely on satellite data, which can be obstructed by clouds.

Key Process: Mesophyll Diffusion

A critical aspect of this new estimate involves a deeper understanding of mesophyll diffusion, which is how OCS and CO2 transition from leaves into chloroplasts for carbon fixation. This understanding is essential for assessing how efficiently plants conduct photosynthesis and adapt to environmental changes.

Expert Insights

Lianhong Gu, a co-author and photosynthesis expert at ORNL, highlighted the importance of updating global GPP estimates. He noted that the previous estimate of 120 petagrams per year had been used for many years, making this new finding crucial for accurate representations of the Earth’s carbon cycle.

Gu stated, “Nailing down our estimates of GPP with reliable global-scale observations is a critical step in improving our predictions of future CO2 in the atmosphere and the consequences for global climate.”

Implications for Rainforests

The study revealed that pan-tropical rainforests accounted for the most significant differences between earlier and current GPP estimates. This discovery indicates that these rainforests serve as more substantial natural carbon sinks than previously believed, emphasizing their importance in global carbon storage.

Conclusion

The new findings shed light on the critical role of terrestrial plants in carbon sequestration, providing a clearer understanding of their impact on the climate. By refining the estimates of GPP and incorporating essential processes like mesophyll conductance into Earth system models, scientists can enhance predictions about future atmospheric CO2 levels and their potential effects on global climate dynamics. This research not only improves our comprehension of carbon cycling but also stresses the importance of preserving and protecting natural ecosystems, particularly tropical forests, in our efforts to combat climate change.

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