Abstract
AbstractAs part of an integrated energy and climate system, biomass production for bioenergy based on the tropical perennial C4 grass energycane can both offset fossil fuels and store soil carbon (C). We measured energycane yields, root biomass, soil C pools, and soil C stocks in a 4 year field trial and modeled C flow from plants to soils in the surface layer of no‐till energycane planted after more than a century of intensive sugarcane agriculture. Aboveground yields ranged from 16.7 to 19.0 Mg C/ha over the 4 year trial. Although total C stocks did not significantly differ in the surface layer (approx. 0–20 cm) during the study, C in free and occluded light fractions decreased, whereas C in the mineral‐rich dense fraction increased over 4 years. Belowground system inputs, estimated from measurements and informed by convergence in the final soil fraction model, were set to 2.5 Mg C ha−1 year−1. With this input value, we estimated that surface soils retained photosynthetically fixed C predominantly within the mineral‐associated organic matter pool for a mean and median transit time of 177 and 110 years, respectively. Although we did not model C flow to deep soil layers (approx. 0–100 cm), observed C accumulation (11.4 Mg C ha−1 year−1) and root growth down to 120 cm suggest that soil processes and resulting C sequestration at the surface are likely to persist deeper into the soil profile. Energycane, as a strong candidate for climate change mitigation and land degradation remediation, showed high biomass yields and allocation of resources to roots, with sequestered soil C expected to persist for over a century.
Highlights
Soil carbon (C) sequestration during biomass production for bioenergy can compound the expected climate benefit derived only from offsetting fossil fuel use, thereby improving its viability as a renewable energy pathway (Whitaker et al, 2018)
As part of an integrated energy and climate system, biomass production for bioenergy based on the tropical perennial C4 grass energycane can both offset fossil fuels and store soil carbon (C)
Free light fraction decreased from 6.3 ± 0.9 to 2.7 ± 0.4 Mg C ha-1 from baseline to Year 4 respectively; occluded light fraction decreased from 16.0 ± 0.8 to 8.3 ± 1.1 Mg C ha-1 from baseline to Year 4 respectively
Summary
Soil carbon (C) sequestration during biomass production for bioenergy can compound the expected climate benefit derived only from offsetting fossil fuel use, thereby improving its viability as a renewable energy pathway (Whitaker et al, 2018). Managed grass-based biofuel crops draw down C from the atmosphere and offset fossil fuel use, and improve ecosystem diversity, health, and resilience (Anderson-Teixeira et al, 2012; DeLucia, 2016). Energy, and climate systems in Hawaii, as in many other tropical and subtropical regions worldwide, will require the restoration of degraded landscapes previously under intensive cultivation (Dallimer & Stringer, 2018; Morgan et al, 2019). It is important to understand and accurately project the potential climate benefits of tropical C4 perennial grass agroecosystems cultivated on degraded lands
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