Prominence of the Tropics in the Recent Rise of Global Nitrogen Pollution

Overview

Journal Nat Commun

Specialty Biology

Date 2019 Mar 31

PMID 30926807

Citations 8

Authors

Minjin Lee

Elena Shevliakova

Charles A Stock

Sergey Malyshev

P C D Milly

Affiliations

Soon will be listed here.

Abstract

Nitrogen (N) pollution is shaped by multiple processes, the combined effects of which remain uncertain, particularly in the tropics. We use a global land biosphere model to analyze historical terrestrial-freshwater N budgets, considering the effects of anthropogenic N inputs, atmospheric CO, land use, and climate. We estimate that globally, land currently sequesters 11 (10-13)% of annual N inputs. Some river basins, however, sequester >50% of their N inputs, buffering coastal waters against eutrophication and society against greenhouse gas-induced warming. Other basins, releasing >25% more than they receive, are mostly located in the tropics, where recent deforestation, agricultural intensification, and/or exports of land N storage can create large N pollution sources. The tropics produce 56 ± 6% of global land N pollution despite covering only 34% of global land area and receiving far lower amounts of fertilizers than the extratropics. Tropical land use should thus be thoroughly considered in managing global N pollution.

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