Weimin Ju scite author profile

The enhanced vegetation productivity driven by increased concentrations of carbon dioxide (CO2) [i.e., the CO2 fertilization effect (CFE)] sustains an important negative feedback on climate warming, but the temporal dynamics of CFE remain unclear. Using multiple long-term satellite- and ground-based datasets, we showed that global CFE has declined across most terrestrial regions of the globe from 1982 to 2015, correlating well with changing nutrient concentrations and availability of soil water. Current carbon cycle models also demonstrate a declining CFE trend, albeit one substantially weaker than that from the global observations. This declining trend in the forcing of terrestrial carbon sinks by increasing amounts of atmospheric CO2 implies a weakening negative feedback on the climatic system and increased societal dependence on future strategies to mitigate climate warming.

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Distributed hydrological model for mapping evapotranspiration using remote sensing inputs

Chen

et al. 2005

Journal of Hydrology

235

197

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Development of a two-leaf light use efficiency model for improving the calculation of terrestrial gross primary productivity

Zhou

et al. 2013

Agricultural and Forest Meteorology

195

192

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Vegetation structural change since 1981 significantly enhanced the terrestrial carbon sink

Chen¹,

Ju²,

Ciais³

et al. 2019

Nat Commun

267

159

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Satellite observations show that leaf area index (LAI) has increased globally since 1981, but the impact of this vegetation structural change on the global terrestrial carbon cycle has not been systematically evaluated. Through process-based diagnostic ecosystem modeling, we find that the increase in LAI alone was responsible for 12.4% of the accumulated terrestrial carbon sink (95 ± 5 Pg C) from 1981 to 2016, whereas other drivers of CO2 fertilization, nitrogen deposition, and climate change (temperature, radiation, and precipitation) contributed to 47.0%, 1.1%, and −28.6% of the sink, respectively. The legacy effects of past changes in these drivers prior to 1981 are responsible for the remaining 65.5% of the accumulated sink from 1981 to 2016. These results refine the attribution of the land sink to the various drivers and would help constrain prognostic models that often have large uncertainties in simulating changes in vegetation and their impacts on the global carbon cycle.

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Weimin Ju

Recent global decline of CO ₂ fertilization effects on vegetation photosynthesis

Distributed hydrological model for mapping evapotranspiration using remote sensing inputs

Development of a two-leaf light use efficiency model for improving the calculation of terrestrial gross primary productivity

Vegetation structural change since 1981 significantly enhanced the terrestrial carbon sink

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Weimin Ju

Recent global decline of CO 2 fertilization effects on vegetation photosynthesis

Distributed hydrological model for mapping evapotranspiration using remote sensing inputs

Development of a two-leaf light use efficiency model for improving the calculation of terrestrial gross primary productivity

Vegetation structural change since 1981 significantly enhanced the terrestrial carbon sink

Contact Info

Product

Resources

About

Recent global decline of CO ₂ fertilization effects on vegetation photosynthesis