AI Article Synopsis

  • Biofuels and bioenergy systems are crucial for reducing fossil fuel use in transportation and achieving negative emissions through carbon capture and storage (CCS), but concerns exist about their overall greenhouse gas benefits due to land use changes.
  • A study analyzed case sites in the US, finding that growing switchgrass for biofuels offers comparable carbon mitigation potential to reforestation and is significantly better than grassland restoration, while using existing forests can result in high carbon debt.
  • Future advancements in energy crop yields and biorefining technologies, combined with CCS, could enhance the mitigation potential of biofuel systems significantly beyond that of traditional land restoration methods, indicating a valid role for biofuels in combating climate change.

Article Abstract

Biofuel and bioenergy systems are integral to most climate stabilization scenarios for displacement of transport sector fossil fuel use and for producing negative emissions via carbon capture and storage (CCS). However, the net greenhouse gas mitigation benefit of such pathways is controversial due to concerns around ecosystem carbon losses from land use change and foregone sequestration benefits from alternative land uses. Here, we couple bottom-up ecosystem simulation with models of cellulosic biofuel production and CCS in order to track ecosystem and supply chain carbon flows for current and future biofuel systems, with comparison to competing land-based biological mitigation schemes. Analyzing three contrasting US case study sites, we show that on land transitioning out of crops or pasture, switchgrass cultivation for cellulosic ethanol production has per-hectare mitigation potential comparable to reforestation and severalfold greater than grassland restoration. In contrast, harvesting and converting existing secondary forest at those sites incurs large initial carbon debt requiring long payback periods. We also highlight how plausible future improvements in energy crop yields and biorefining technology together with CCS would achieve mitigation potential 4 and 15 times greater than forest and grassland restoration, respectively. Finally, we show that recent estimates of induced land use change are small relative to the opportunities for improving system performance that we quantify here. While climate and other ecosystem service benefits cannot be taken for granted from cellulosic biofuel deployment, our scenarios illustrate how conventional and carbon-negative biofuel systems could make a near-term, robust, and distinctive contribution to the climate challenge.

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Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7486778PMC
http://dx.doi.org/10.1073/pnas.1920877117DOI Listing

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