Abstract
AbstractOver the past century, increased atmospheric CO2 concentrations have enhanced photosynthesis through CO2 fertilization across the globe. However, the increased growth has also led to greater respiration rates—both from vegetation (autotrophic respiration) and through the breakdown of plant litter and soil organic matter (heterotrophic respiration). The resulting change in carbon flux—and its spatial distribution—that can be attributed to increasing CO2 and climate change remains unknown. We used the Carbon Data Model Framework, a model‐data fusion system that assimilates global observations from satellites and other sources to create an ensemble of observationally constrained carbon cycle representations, to determine the photosynthesis and respiration fluxes that can be attributed to increased atmospheric CO2 and associated climate change from 1920 to 2015. Across the globe, the response of photosynthesis and respiration to atmospheric CO2 dominates their response to climate alone. The regional distribution of the carbon sink attributable to climate change and CO2 is strongly influenced by the 'loss ratio of carbon gained'—the fraction of enhanced photosynthesis that is lost to respiration. While the wet tropics' attributable photosynthesis flux is 1.4 times larger than that of the temperate region, the attributable flux of net carbon uptake is actually 1.25 larger in the temperate region, due to the wet tropics' greater heterotrophic respiration response to enhanced plant growth. At the global scale, the loss ratio of carbon gained is 83 ± 0.6%. Our results highlight the importance of the respiration responses to enhanced plant growth in regulating the land carbon sink.
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