Nitrogen (N) and phosphorus (P) limitation constrains the magnitude of terrestrial carbon
uptake in response to elevated carbon dioxide and climate change. However, global maps …

The size of the terrestrial sink remains uncertain. This uncertainty presents a challenge for
projecting future climate–carbon cycle feedbacks,,,. Terrestrial carbon storage is dependent …

Terrestrial carbon (C) cycle models applied for climate projections simulate a strong
increase in net primary productivity (NPP) due to elevated atmospheric CO 2 concentration …

Increased human‐derived nitrogen (N) deposition to terrestrial ecosystems has resulted in
widespread phosphorus (P) limitation of net primary productivity. However, it remains …

Increased human‐derived nitrogen (N) loading in terrestrial ecosystems has caused
widespread ecosystem‐level phosphorus (P) limitation. In response, plants and soil micro …

A highly controversial issue in global biogeochemistry is the regulation of terrestrial carbon
(C) sequestration by soil nitrogen (N) availability. This controversy translates into great …

Global net land carbon uptake or net biome production (NBP) has increased during recent
decades. Whether its temporal variability and autocorrelation have changed during this …

Because the capability of terrestrial ecosystems to fix carbon is constrained by nutrient
availability, understanding how nutrients limit plant growth is a key contemporary question …

Carbon‐climate feedback has been identified as one of the key areas of synthesis for the
next Inter‐governmental Panel on Climate Change (IPCC); however, most of the models on …

Nutrient limitation is pervasive in the terrestrial biosphere, although the relationship between
global carbon (C) nitrogen (N) and phosphorus (P) cycles remains uncertain. Using meta …