AI Article Synopsis
- - The study examines how human land-use changes impact nitrogen (N) cycling in ecosystems, which is vital for food security, using data from 2430 global observations.
- - Converting natural ecosystems to managed ones increases nitrogen losses through leaching and gas emissions, resulting in a "leaky" N cycle, while reversing this change can improve nitrogen retention by over 100%.
- - Key factors affecting N retention after land-use changes include soil organic carbon, pH, and carbon to nitrogen ratios, with critical leaky N cycle regions identified in tropical areas, Western Europe, the U.S., and China.
Article Abstract
Anthropogenic land-use practices influence ecosystem functions and the environment. Yet, the effect of global land-use change on ecosystem nitrogen (N) cycling remains unquantified despite that ecosystem N cycling plays a critical role in maintaining food security. Here, we analysed 2430 paired observations globally to show that converting natural to managed ecosystems increases ratios of autotrophic nitrification to ammonium immobilisation and nitrate to ammonium, but decreases soil immobilisation of mineral N, causing increased N losses via leaching and gaseous N emissions, such as nitrous oxide (e.g., via denitrification), resulting in a leaky N cycle. Changing land use from intensively managed to one that resembles natural ecosystems reversed N losses by 108% on average, resulting in a more conservative N cycle. Structural equation modelling revealed that changes in soil organic carbon, pH and carbon to N ratio were more important than changes in soil moisture content and temperature in predicting ecosystem N retention capacities following land-use conversion and its reversion. The hotspots of leaky N cycles were mostly in equatorial and tropical regions, as well as in Western Europe, the United States and China. Our results suggest that whether an ecosystem exhibits a conservative N cycle after land-use reversion depends on management practices.
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| http://dx.doi.org/10.1111/gcb.17537 | DOI Listing |
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