The effects of spatiotemporal patterns of atmospheric CO 2 concentration on terrestrial gross primary productivity estim
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The effects of spatiotemporal patterns of atmospheric CO2 concentration on terrestrial gross primary productivity estimation Zhongyi Sun 1,2 Tangzhe Nie 5
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& Xiufeng Wang & Haruhiko Yamamoto & Hiroshi Tani &
Received: 21 June 2018 / Accepted: 19 October 2020/ # Springer Nature B.V. 2020
Abstract
A quantitative understanding of the global gross primary productivity (GPP) and its responses to increasing CO2 levels is critical for quantifying the feedbacks of ecosystems to climate change. This study applied the daily boreal ecosystem productivity simulator (BEPSd) model to estimate the global GPP from 2000 to 2015, compare the estimated GPP with flux tower measurements and other GPP products to verify the estimation accuracy, and analyze the CO2 fertilization effect and conducted a spatial analysis of the effects of the spatiotemporal distribution of the CO2 concentration on the estimation of the GPP. The results showed that the estimates could capture the magnitude, amplitude, distribution, and variation in the GPP well compared with the flux tower measurements and other GPP products. In general, the terrestrial GPP increased as the atmospheric CO2 concentrations increased; however, the CO2 fertilization effect varied based on time and location and was constrained by climatic conditions. The increases in the lower latitudes were more significant than those in the middle and higher latitudes, and seasonal variation characteristics were observed in the middle and higher latitudes. Not considering the CO2 fertilization effect could underestimate the global GPP and its trend, while not considering the spatiotemporal distribution of the CO2 concentration could overestimate the global annual GPP. These results increase our understanding of the variations in carbon flux under future climate change, especially under the conditions of a changing atmospheric CO2 concentration. Keywords Gross primary productivity (GPP) . Atmospheric CO2 concentration . Daily boreal ecosystem productivity simulator (BEPSd) . Global spatiotemporal variability
* Zhongyi Sun [email protected] Extended author information available on the last page of the article
Climatic Change
1 Introduction The terrestrial gross primary productivity (GPP), which is defined as the amount of carbon uptake by vegetation through photosynthesis at the ecosystem scale, is the first step of atmospheric CO2 entering the biosphere (Hilker et al. 2008; Beer et al. 2010; Zhang et al. 2017). As previously reported, the increase in atmospheric CO2 is the major cause of global climate change (Hartmann et al. 2013, IPCC AR5), and over the past century, the CO2 accumulation rate has continuously increased given the amount of CO2 released due to landcover changes and fossil fuel combustion (Le Quéré et al. 2016). Through the GPP, which constitutes the largest global land carbon flux (Zhao and Running 2010; Beer et al. 2010) and plays a pivotal role in almost all ecosystem processes, terrestrial ecosystems can partially mitigate global warming and offse
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