African biomes are most sensitive to changes in CO.sub.2 under recent and near-future CO.sub.2 conditions

Current rates of climate and atmospheric change are likely higher than during the last millions of years. Even higher rates of change are projected in CMIP5 climate model ensemble runs for some Representative Concentration Pathway (RCP) scenarios. The speed of ecological processes such as leaf physi...

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Veröffentlicht in:	Biogeosciences 2020-02, Vol.17 (4), p.1147
Hauptverfasser:	Scheiter, Simon, Moncrieff, Glenn R, Pfeiffer, Mirjam, Higgins, Steven I
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Sprache:	eng
Schlagworte:	Air pollution Biomes Climate models Environmental quality Fossils Greenhouse gases Physiological aspects
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creator	Scheiter, Simon Moncrieff, Glenn R Pfeiffer, Mirjam Higgins, Steven I
description	Current rates of climate and atmospheric change are likely higher than during the last millions of years. Even higher rates of change are projected in CMIP5 climate model ensemble runs for some Representative Concentration Pathway (RCP) scenarios. The speed of ecological processes such as leaf physiology, demography or migration can differ from the speed of changes in environmental conditions. Such mismatches imply lags between the actual vegetation state and the vegetation state expected under prevailing environmental conditions. Here, we used a dynamic vegetation model, the adaptive Dynamic Global Vegetation Model (aDGVM), to study lags between actual and expected vegetation in Africa under a changing atmospheric CO.sub.2 mixing ratio. We hypothesized that lag size increases with a more rapidly changing CO.sub.2 mixing ratio as opposed to slower changes in CO.sub.2 and that disturbance by fire further increases lag size. Our model results confirm these hypotheses, revealing lags between vegetation state and environmental conditions and enhanced lags in fire-driven systems. Biome states, carbon stored in vegetation and tree cover in Africa are most sensitive to changes in CO.sub.2 under recent and near-future levels. When averaged across all biomes and simulations with and without fire, times to reach an equilibrium vegetation state increase from approximately 242 years for 200 ppm to 898 years for 1000 ppm. These results have important implications for vegetation modellers and for policy making. Lag effects imply that vegetation will undergo substantial changes in distribution patterns, structure and carbon sequestration even if emissions of fossils fuels and other greenhouse gasses are reduced and the climate system stabilizes. We conclude that modelers need to account for lag effects in models and in data used for model testing. Policy makers need to consider lagged responses and committed changes in the biosphere when developing adaptation and mitigation strategies.
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subjects	Air pollution Biomes Climate models Environmental quality Fossils Greenhouse gases Physiological aspects
title	African biomes are most sensitive to changes in CO.sub.2 under recent and near-future CO.sub.2 conditions
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