Modeled gross primary productivity (GPP) for tropical and subtropical zones with ORCHIDEE-CNP. a GPP from ORCHIDEE-CNP simulations assuming N constraints but a high P everywhere (no P constraint). b GPP as in a, but including P constraints according to a version of the multiple regression in Table 2. The color scale for a, b are at top. c the difference between GPP from the model with N but not P constraints as shown in a and the ORCHIDEE-CNP simulations with P constraints according to b, with color scale at bottom. (d) the zonal difference in GPP shown in c using 2˚ latitudinal bands and aggregated across longitudes around the globe. Credit: Nature Communications (2022). DOI: 10.1038/s41467-022-32545-0
A new international study led by Western Sydney University researchers has quantified phosphorus constraints to photosynthesis in tropical forests, highlighting how accounting for this constraint can improve the world’s climate.
Tropical forests have an important role in the carbon cycle, absorbing more carbon from the atmosphere than any other ecosystem, and acting as key modulators of the global climate.
Despite being hotspots for biodiversity and range among the most productive ecosystems on the planet, they typically lack phosphorus—a major plant nutrient—which limits photosynthesis.
As part of the study published in Nature Communications, the research team performed the most comprehensive analysis to date across 12 different countries and took nearly 18,000 measurements to understand the link between phosphorus and photosynthesis.
Lead author Professor David Ellsworth from the Hawkesbury Institute for the Environment said the study reinforces that the higher the concentration of phosphorus in leaves, the higher their capacity to absorb carbon dioxide.
“For the first time, the analysis has established that phosphorus is a considerable constraint on the photosynthetic capacity of leaves worldwide,” said Professor Ellsworth.
“This finding has far-reaching implications considering that over a third of the world’s soils are below optimal phosphorus, as illustrated by the positive response of plant growth to the addition of phosphorus in the form of fertilizer.”
According to Professor Ellsworth, understanding photosynthesis and its environmental impact is pivotal for predicting the response of all the world’s ecosystems to the increasing atmospheric carbon dioxide concentrations and climate change, and therefore for predicting future climate change possibilities.
“The findings expand the available knowledge of how the world’s ecosystems are responding to climate change. It not only affects our understanding of the role tropical forests have in global climate change but creates opportunities to enhance the productivity of the forests themselves,” said Professor Ellsworth.
As part of the study, the research team derived a mathematical formulation that depicts the link between photosynthesis and leaf phosphorus and used it within one of the few global biosphere models which incorporates phosphorus cycling.
The modeling demonstrated how the discovery can be beneficial in predicting global photosynthesis, showing that tropical forests could absorb much more carbon from the atmosphere if these ecosystems were richer in phosphorus than they currently are.
Further information: David S. Ellsworth et al, Convergence in phosphorus constraints to photosynthesis in forests around the world, Nature Communications (2022). DOI: 10.1038/s41467-022-32545-0
Journal information: Nature Communications
Source: Western Sydney University