Abstract
Effective soil management is critical to achieving climate change mitigation in plant-based renewable energy systems, yet limitations exist in our understanding of dynamic belowground responses to the cultivation of energy crops. To better understand the belowground dynamics following cultivation of a grassland in a high-yielding tropical perennial C4 grass in a zero-tillage production system, changes in soil carbon (C) pools were quantified, modeled, and projected and the chemical composition of the aggregate-protected pool was determined. Multiple C pools with different ecosystem functions and turnover increased following cultivation: immediately available microbial substrate (measured as hot water-soluble C) and active C (determined through laboratory incubation) increased by 12% and 30% respectively over time and soil C accumulated significantly in multiple physical fractions. A more rapid and dynamic nature of multiple C pools and transfers between pools existed than is often assumed in belowground models used widely in the field to simulate soil C accumulation. Multiple indicators of fresh roots, including the more easily degraded lignin monomers and root-derived long chain substituted fatty acids, appeared in aggregate-protected pools of cultivated soils over time since planting. This rapid transfer of plant inputs through active and intermediate C pools into mineral-dominated pools is the ultimate outcome required for building soil C stocks. Initial model runs suggested that this is evident, even on a two-year frame, in transfer rates of 0.485 and 0.890 from active to slow and slow to passive pools respectively. The rapid transfer of fresh root-derived input to stable pool suggests that soil C under zero-tillage management may be resilient to disturbances, such as replanting following a kill-harvest, that would otherwise result in losses from unprotected or readily available pools.
Highlights
Soil carbon (C) loss as a result of land use change during cultivation of biofuel feedstocks negatively impacts the net global warming mitigation potential of a renewable fuel production system (Gibbs et al, 2008; DeLucia, 2016), but losses can be minimized, or C accrued, with sustainable management practices (Cornelissen et al, 2013; Gelfand et al, 2013)
Soil organic matter is a dynamic C pool that is responsive to disturbances such as land preparation for cultivation and subsequent crop choice and management practices (Shrestha et al, 2015)
Understanding the processes controlling the belowground C dynamics is a critical component to predicting the net soil C change during cultivation of biofuel feedstocks in different biomes, and to planning a production system with no net change or, ideally, a net gain in soil C over time
Summary
Soil carbon (C) loss as a result of land use change during cultivation of biofuel feedstocks negatively impacts the net global warming mitigation potential of a renewable fuel production system (Gibbs et al, 2008; DeLucia, 2016), but losses can be minimized, or C accrued, with sustainable management practices (Cornelissen et al, 2013; Gelfand et al, 2013). (2) It was hypothesized that the extensive belowground root systems and associated rhizosphere of a cultivated tropical perennial C4 grass would increase both the active (i.e., readily available, labile, and unprotected organic debris) and the aggregate-protected C pools to result in the previously observed C accumulation in the whole soil.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
