生物能源
环境科学
土壤碳
温室气体
生物地球化学循环
土壤有机质
生物燃料
土壤水分
生态学
土壤科学
化学
环境化学
生物
作者
Danielle Berardi,Edward Brzostek,Elena Blanc‐Betes,Brian H. Davison,Evan H. DeLucia,Melannie D. Hartman,Jeffrey Kent,William J. Parton,Debasish Saha,T. W. Hudiburg
出处
期刊:Gcb Bioenergy
[Wiley]
日期:2020-07-22
卷期号:12 (10): 774-788
被引量:80
摘要
Abstract 21st‐century modeling of greenhouse gas (GHG) emissions from bioenergy crops is necessary to quantify the extent to which bioenergy production can mitigate climate change. For over 30 years, the Century‐based biogeochemical models have provided the preeminent framework for belowground carbon and nitrogen cycling in ecosystem and earth system models. While monthly Century and the daily time‐step version of Century (DayCent) have advanced our ability to predict the sustainability of bioenergy crop production, new advances in feedstock generation, and our empirical understanding of sources and sinks of GHGs in soils call for a re‐visitation of DayCent's core model structures. Here, we evaluate current challenges with modeling soil carbon dynamics, trace gas fluxes, and drought and age‐related impacts on bioenergy crop productivity. We propose coupling a microbial process‐based soil organic carbon and nitrogen model with DayCent to improve soil carbon dynamics. We describe recent improvements to DayCent for simulating unique plant structural and physiological attributes of perennial bioenergy grasses. Finally, we propose a method for using machine learning to identify key parameters for simulating N 2 O emissions. Our efforts are focused on meeting the needs for modeling bioenergy crops; however, many updates reviewed and suggested to DayCent will be broadly applicable to other systems.
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