Estimating global cropland production from 1961 to 2010

Pengfei Han,Fang Zhao,Ning Zeng,Xiaohui Lin

doi:10.5194/esd-8-875-2017

Abstract

Abstract. Global cropland net primary production (NPP) has tripled over the last 50 years, contributing 17–45 % to the increase in global atmospheric CO2 seasonal amplitude. Although many regional-scale comparisons have been made between statistical data and modeling results, long-term national comparisons across global croplands are scarce due to the lack of detailed spatiotemporal management data. Here, we conducted a simulation study of global cropland NPP from 1961 to 2010 using a process-based model called Vegetation–Global Atmosphere–Soil (VEGAS) and compared the results with Food and Agriculture Organization of the United Nations (FAO) statistical data on both continental and country scales. According to the FAO data, the global cropland NPP was 1.3, 1.8, 2.2, 2.6, 3.0, and 3.6 PgC yr−1 in the 1960s, 1970s, 1980s, 1990s, 2000s, and 2010s, respectively. The VEGAS model captured these major trends on global and continental scales. The NPP increased most notably in the US Midwest, western Europe, and the North China Plain and increased modestly in Africa and Oceania. However, significant biases remained in some regions such as Africa and Oceania, especially in temporal evolution. This finding is not surprising as VEGAS is the first global carbon cycle model with full parameterization representing the Green Revolution. To improve model performance for different major regions, we modified the default values of management intensity associated with the agricultural Green Revolution differences across various regions to better match the FAO statistical data at the continental level and for selected countries. Across all the selected countries, the updated results reduced the RMSE from 19.0 to 10.5 TgC yr−1 (∼ 45 % decrease). The results suggest that these regional differences in model parameterization are due to differences in socioeconomic development. To better explain the past changes and predict the future trends, it is important to calibrate key parameters on regional scales and develop data sets for land management history.

Highlights

Cropland net primary production (NPP) plays a crucial role in both food security and atmospheric CO2 variations
China began participating in the Green Revolution in the 1970s, with hybrid rice bred by Longping Yuan (Yuan, 1966), and the fertilizer application rate increased dramatically from 43 kg ha−1 in 1970 to 346 kg ha−1 in 1995 (Hazell, 2009)
Brazil began participating in the Green Revolution in the 1970s, and in collaboration with CIMMYT, high-yielding wheat varieties with aluminum toxicity resistance, which were efficient in dealing with the aluminum toxicity in the Cerrado soils of Brazil were developed (Davies, 2003; Khush, 2001)

Summary

Introduction

Cropland net primary production (NPP) plays a crucial role in both food security and atmospheric CO2 variations. It has been reported that the increase in cropland NPP driven by the agricultural Green Revolution contributed 17–45 % of the increase in atmospheric CO2 seasonal amplitude (Gray et al, 2014; Zeng et al, 2014). Agricultural areas cover ∼ 1370 million hectares, distributed across diverse climatic and edaphic conditions, with a variety of complex cropping systems and management practices Han et al.: Estimating global cropland production from 1961 to 2010

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