Litcius/Paper detail

Climate change determines the sign of productivity trends in US forests

J. Aaron Hogan, Grant M. Domke, Kai Zhu, Daniel J. Johnson, Jeremy W. Lichstein

2024Proceedings of the National Academy of Sciences53 citationsDOIOpen Access PDF

Abstract

Forests are integral to the global land carbon sink, which has sequestered ~30% of anthropogenic carbon emissions over recent decades. The persistence of this sink depends on the balance of positive drivers that increase ecosystem carbon storage—e.g., CO 2 fertilization—and negative drivers that decrease it—e.g., intensifying disturbances. The net response of forest productivity to these drivers is uncertain due to the challenge of separating their effects from background disturbance–regrowth dynamics. We fit non-linear models to US forest inventory data (113,806 plot remeasurements in non-plantation forests from ~1999 to 2020) to quantify productivity trends while accounting for stand age, tree mortality, and harvest. Productivity trends were generally positive in the eastern United States, where climate change has been mild, and negative in the western United States, where climate change has been more severe. Productivity declines in the western United States cannot be explained by increased mortality or harvest; these declines likely reflect adverse climate-change impacts on tree growth. In the eastern United States, where data were available to partition biomass change into age-dependent and age-independent components, forest maturation and increasing productivity (likely due, at least in part, to CO 2 fertilization) contributed roughly equally to biomass carbon sinks. Thus, adverse effects of climate change appear to overwhelm any positive drivers in the water-limited forests of the western United States, whereas forest maturation and positive responses to age-independent drivers contribute to eastern US carbon sinks. The future land carbon balance of forests will likely depend on the geographic extent of drought and heat stress.

Topics & Concepts

Climate changeCarbon sinkProductivityEnvironmental scienceSink (geography)EcosystemCarbon sequestrationBiomass (ecology)Forest inventoryLand use, land-use change and forestryEcologyForest dynamicsForest managementLand useGeographyAgroforestryBiologyCarbon dioxideEconomicsCartographyMacroeconomicsPlant Water Relations and Carbon DynamicsFire effects on ecosystemsForest ecology and management