Adaptation in U.S. Corn Belt increases resistance to soil carbon loss with climate change

Yao Zhang,Daniel Bader,Ernie Marx,Radley Horton,Keith Paustian,Stephen Williams,Stephen Ogle,Ram Gurung

doi:10.1038/s41598-020-70819-z

Yao Zhang, Daniel Bader + Show 6 more

Open Access

https://doi.org/10.1038/s41598-020-70819-z

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Journal: Scientific Reports	Publication Date: Aug 14, 2020
Citations: 9	License type: open-access

Affiliation: Colorado State University, Columbia University

Abstract

Increasing the amount of soil organic carbon (SOC) has agronomic benefits and the potential to mitigate climate change. Previous regional predictions of SOC trends under climate change often ignore or do not explicitly consider the effect of crop adaptation (i.e., changing planting dates and varieties). We used the DayCent biogeochemical model to examine the effect of adaptation on SOC for corn and soybean production in the U.S. Corn Belt using climate data from three models. Without adaptation, yields of both corn and soybean tended to decrease and the decomposition of SOC tended to increase leading to a loss of SOC with climate change compared to a baseline scenario with no climate change. With adaptation, the model predicted a substantially higher crop yield. The increase in yields and associated carbon input to the SOC pool counteracted the increased decomposition in the adaptation scenarios, leading to similar SOC stocks under different climate change scenarios. Consequently, we found that crop management adaptation to changing climatic conditions strengthen agroecosystem resistance to SOC loss. However, there are differences spatially in SOC trends. The northern part of the region is likely to gain SOC while the southern part of the region is predicted to lose SOC.

Highlights

Increasing the amount of soil organic carbon (SOC) has agronomic benefits and the potential to mitigate climate change
Without adaptation, the average corn yield during the 2041–2071 period in the Corn Belt would drop in all three General Circulation Models (GCMs) climate scenarios in comparison with the baseline with no climate change (Fig. 1)
Two GCMs (GFDL-CM3 and MRI-CGCM3) predicted similar changes over time as the baseline, while the SOC values for the other GCM (MIROC-ESM) were slightly lower than the baseline. These results show that adaptation with the selection of longer-season varieties can lead to a similar SOC level as the baseline and GCM scenarios under a moderate climate change projection (RCP 4.5)

Summary

Limitations

We did not evaluate the possibility of new technologies that could be developed in the future and influence production, decomposition and other variables influencing SOC levels, as these changes are difficult to predict. New technologies associated with crop breeding and other genetic improvements, pest control, and other developments could increase C input and result in higher SOC stocks than our predictions. Management practices such as adding cover crops, which increases C input, may further enhance SOC stocks[23]. Future research should address subsoil C dynamics

Conclusions

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