Remobilization of southern African desert dune systems by twenty-first century global warming

Remobilization of southern African desert dune systems by twenty-first century global warming

Although desert dunes cover 5 per cent of the global land surface and 30 per cent of Africa, the potential impacts of twenty-first century global warming on desert dune systems are not well understood. The inactive Sahel and southern African dune systems, which developed in multiple arid phases sinc...

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Bibliographic Details
Published in:Nature Vol. 435; no. 7046; pp. 1218 - 1221
Main Authors: Wiggs, Giles F. S, Knight, Melanie, Thomas, David S. G
Format: Journal Article
Language:English
Published: London Nature Publishing 30-06-2005
Nature Publishing Group
Subjects:
Atmosphere - chemistry
Atmospheric models
Climate change
Climate models
Computer Simulation
Desert Climate
Deserts
Dunes
Earth sciences
Earth, ocean, space
Ecosystem
Emissions
Environmental impact
Exact sciences and technology
Farming systems
Global climate
Global warming
Greenhouse Effect
Humidity
Interglacial periods
Marine and continental quaternary
Moisture availability
Plant Development
Population Dynamics
Precipitation
Rain
Seasons
Sediment transport
Silicon Dioxide - analysis
South Africa
Surficial geology
Time Factors
Vegetation cover
Wind power
Angola
Kalahari Desert
Southern Africa
South Africa
Zambia
Central Africa
East Africa
Africa
models
mobility
erodibility
simulation
Africa
vegetation
remobilization
dynamics
deserts
dunes
climate modification
global warming
wind erosion
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Summary:Although desert dunes cover 5 per cent of the global land surface and 30 per cent of Africa, the potential impacts of twenty-first century global warming on desert dune systems are not well understood. The inactive Sahel and southern African dune systems, which developed in multiple arid phases since the last interglacial period, are used today by pastoral and agricultural systems that could be disrupted if climate change alters twenty-first century dune dynamics. Empirical data and model simulations have established that the interplay between dune surface erodibility (determined by vegetation cover and moisture availability) and atmospheric erosivity (determined by wind energy) is critical for dunefield dynamics. This relationship between erodibility and erosivity is susceptible to climate-change impacts. Here we use simulations with three global climate models and a range of emission scenarios to assess the potential future activity of three Kalahari dunefields. We determine monthly values of dune activity by modifying and improving an established dune mobility index so that it can account for global climate model data outputs. We find that, regardless of the emission scenario used, significantly enhanced dune activity is simulated in the southern dunefield by 2039, and in the eastern and northern dunefields by 2069. By 2099 all dunefields are highly dynamic, from northern South Africa to Angola and Zambia. Our results suggest that dunefields are likely to be reactivated (the sand will become significantly exposed and move) as a consequence of twenty-first century climate warming.
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ISSN:0028-0836
1476-4687
DOI:10.1038/nature03717