Global urban expansion offsets climate-driven increases in terrestrial net primary productivity

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作者
Xiaoping Liu
Fengsong Pei
Youyue Wen
Xia Li
Shaojian Wang
Changjiang Wu
Yiling Cai
Jianguo Wu
Jun Chen
Kuishuang Feng
Junguo Liu
Klaus Hubacek
Steven J. Davis
Wenping Yuan
Le Yu
Zhu Liu
机构
[1] Sun Yat-sen University,School of Geography and Planning
[2] Jiangsu Normal University,School of Geography, Geomatics, and Planning
[3] East China Normal University,School of Geographic Sciences
[4] Massachusetts Institute of Technology,Department of Urban Studies and Planning
[5] Arizona State University,School of Life Sciences & School of Sustainability, Global Institute of Sustainability
[6] National Geomatics Center of China,Department of Geographical Sciences
[7] University of Maryland,School of Environmental Science and Engineering
[8] Southern University of Science and Technology,Center for Energy and Environmental Sciences (IVEM)
[9] Energy and Sustainability Research Institute Groningen (ESRIG),Department of Environmental Studies
[10] Masaryk University,Department of Earth System Science
[11] International Institute for Applied Systems Analysis,Department of Earth System Science
[12] University of California,undefined
[13] Tsinghua University,undefined
来源
Nature Communications | / 10卷
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摘要
The global urbanization rate is accelerating; however, data limitations have far prevented robust estimations of either global urban expansion or its effects on terrestrial net primary productivity (NPP). Here, using a high resolution dataset of global land use/cover (GlobeLand30), we show that global urban areas expanded by an average of 5694 km2 per year between 2000 and 2010. The rapid urban expansion in the past decade has in turn reduced global terrestrial NPP, with a net loss of 22.4 Tg Carbon per year (Tg C year−1). Although small compared to total terrestrial NPP and fossil fuel carbon emissions worldwide, the urbanization-induced decrease in NPP offset 30% of the climate-driven increase (73.6 Tg C year−1) over the same period. Our findings highlight the urgent need for global strategies to address urban expansion, enhance natural carbon sinks, and increase agricultural productivity.
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