Decreasing net primary production due to drought and slight decreases in solar radiation in China from 2000 to 2012
AffiliationUniv Arizona, Sch Nat Resources & Environm
MetadataShow full item record
PublisherAMER GEOPHYSICAL UNION
CitationDecreasing net primary production due to drought and slight decreases in solar radiation in China from 2000 to 2012 2017, 122 (1):261 Journal of Geophysical Research: Biogeosciences
Rights©2017. American Geophysical Union. All Rights Reserved.
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AbstractTerrestrial ecosystems have continued to provide the critical service of slowing the atmospheric CO2 growth rate. Terrestrial net primary productivity (NPP) is thought to be a major contributing factor to this trend. Yet our ability to estimate NPP at the regional scale remains limited due to large uncertainties in the response of NPP to multiple interacting climate factors and uncertainties in the driver data sets needed to estimate NPP. In this study, we introduced an improved NPP algorithm that used local driver data sets and parameters in China. We found that bias decreased by 30% for gross primary production (GPP) and 17% for NPP compared with the widely used global GPP and NPP products, respectively. From 2000 to 2012, a pixel-level analysis of our improved NPP for the region of China showed an overall decreasing NPP trend of 4.65TgCa(-1). Reductions in NPP were largest for the southern forests of China (-5.38TgCa(-1)), whereas minor increases in NPP were found for North China (0.65TgCa(-1)). Surprisingly, reductions in NPP were largely due to decreases in solar radiation (82%), rather than the more commonly expected effects of drought (18%). This was because for southern China, the interannual variability of NPP was more sensitive to solar radiation (R-2 in 0.29-0.59) relative to precipitation (R-2<0.13). These findings update our previous knowledge of carbon uptake responses to climate change in terrestrial ecosystems of China and highlight the importance of shortwave radiation in driving vegetation productivity for the region, especially for tropical forests.
Note6 month embargo; First published: 30 January 2017
VersionFinal published version
SponsorsNational Natural Science Foundation of China ; Key Project in the National Science and Technology Pillar program of China [2013BAC03B00]; U.S. National Science Foundation (NSF) EPSCoR program [NSF-IIA-1301789]; NASA Earth Observing system MODIS grant [NNX08AG87A]