Sorghum biomass production in the continental United States and its potential impacts on soil organic carbon and nitrous oxide emissions

Gautam, Sagar; Mishra, Umakant; Scown, Corinne D.; Zhang, Yao

doi:10.1111/gcbb.12736

Cited by 30 publications

(29 citation statements)

References 62 publications

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“…As the energy sorghum system reaches steady state, the C and N fluxes are likely to shift drastically to reflect the perpetual reduction in biomass C and N inputs (Jin et al, 2014; Kent et al, 2020). Recent model‐based work showed the potential for energy sorghum to increase soil organic C through root biomass input in regions of the United States where rainfall, temperature and moisture availability facilitate high growth rates (Gautam et al, 2020). However, this study was based on broad assumptions made regarding agronomic management and the energy sorghum variety used (Gautam et al, 2020), so further observational studies of long‐term ecosystem C and N pools and fluxes are needed to fine‐tune models that assess the long‐term differences between these three bioenergy crop candidates.…”

Section: Discussionmentioning

confidence: 99%

“…drought, floods and frost) and for assessing inter‐annual biogeochemical differences. Perhaps most uncertain for energy sorghum are its long‐term effects on soil organic C due to the high amount of biomass removed during harvest with little stover return (Dou et al, 2014; Gautam et al, 2020; Mitchell et al, 2016). A detailed understanding of the interaction between crop type, climate and management will be critical for forecasting the long‐term sustainability of these key bioenergy crops that will play an important role in ensuring the United States meets its future cellulosic bioenergy requirements.…”

Section: Discussionmentioning

confidence: 99%

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Ecosystem‐scale biogeochemical fluxes from three bioenergy crop candidates: How energy sorghum compares to maize and miscanthus

et al. 2020

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Perennial crops have been the focus of bioenergy research and development for their sustainability benefits associated with high soil carbon (C) and reduced nitrogen (N) requirements. However, perennial crops mature over several years and their sustainability benefits can be negated through land reversion. A photoperiod‐sensitive energy sorghum (Sorghum bicolor) may provide an annual crop alternative more ecologically sustainable than maize (Zea mays) that can more easily integrate into crop rotations than perennials, such as miscanthus (Miscanthus × giganteus). This study presents an ecosystem‐scale comparison of C, N, water and energy fluxes from energy sorghum, maize and miscanthus during a typical growing season in the Midwest United States. Gross primary productivity (GPP) was highest for maize during the peak growing season at 21.83 g C m−2 day−1, followed by energy sorghum (17.04 g C m−2 day−1) and miscanthus (15.57 g C m−2 day−1). Maize also had the highest peak growing season evapotranspiration at 5.39 mm day−1, with energy sorghum and miscanthus at 3.81 and 3.61 mm day−1, respectively. Energy sorghum was the most efficient water user (WUE), while maize and miscanthus were comparatively similar (3.04, 1.75 and 1.89 g C mm−1 H2O, respectively). Maize albedo was lower than energy sorghum and miscanthus (0.19, 0.26 and 0.24, respectively), but energy sorghum had a Bowen ratio closer to maize than miscanthus (0.12, 0.13 and 0.21, respectively). Nitrous oxide (N2O) flux was higher from maize and energy sorghum (8.86 and 12.04 kg N ha−1, respectively) compared with miscanthus (0.51 kg N ha−1), indicative of their different agronomic management. These results are an important first look at how energy sorghum compares to maize and miscanthus grown in the Midwest United States. This quantitative assessment is a critical component for calibrating biogeochemical and ecological models used to forecast bioenergy crop growth, productivity and sustainability.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Ecosystem‐scale biogeochemical fluxes from three bioenergy crop candidates: How energy sorghum compares to maize and miscanthus

et al. 2020

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“…For the current state-of-technology scenario, the soil organic carbon (SOC) sequestration potential of biomass sorghum, on average, of -0.46 metric tons of CO2e/ha 20,21 and electricity generated onsite offset 18% and 44% of the total GHG emissions from DMCO production stages, respectively(Fig. 4-a).…”

Section: Carbon Footprint Of Dmcomentioning

confidence: 99%

Production Cost and Carbon Footprint of Biomass-Derived Dimethylcyclooctane as a High Performance Jet Fuel Blendstock

Baral¹,

Yang²,

Harvey³

et al. 2021

Preprint

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<div> <div> <div> <p>Near-term decarbonization of aviation requires energy-dense, renewable liquid fuels. Biomass- derived 1,4-dimethylcyclooctane (DMCO), a cyclic alkane with a volumetric net heat of combustion up to 9.2% higher than Jet-A, has the potential to serve as a low-carbon, high- performance jet fuel blendstock that may enable paraffinic bio-jet fuels to operate without aromatic compounds. DMCO can be produced from bio-derived isoprenol (3-methyl-3-buten-1- ol) through a multi-step upgrading process. This study presents detailed process configurations for DMCO production to estimate the minimum selling price and life-cycle greenhouse gas (GHG) footprint considering three different hydrogenation catalysts and two bioconversion pathways. The platinum-based catalyst offers the lowest production cost and GHG footprint of $9.0/L-Jet-Aeq and 61.4 gCO2e/MJ, given the current state of technology. However, when the conversion process is optimized, hydrogenation with a Raney nickel catalyst is preferable, resulting in a $1.5/L-Jet-Aeq cost and 18.3 gCO2e/MJ GHG footprint if biomass sorghum is the feedstock. This price point requires dramatic improvements, including 28 metric-ton/ha sorghum yield and 95-98% of the theoretical maximum conversion of biomass-to-sugars, sugars-to-isoprenol, isoprenol-to-isoprene, and isoprene-to-DMCO. Because increased gravimetric energy density of jet fuels translates to reduced aircraft weight, DMCO also has the potential to improve aircraft efficiency, particularly on long-haul flights. </p> </div> </div> </div>

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“…This net SOC sequestration factor reduces the GHG footprint by an average of 25% (Figure 2b). The SOC sequestration potential of biomass sorghum depends on sitespecific biomass yield, nutrient application, irrigation, soil type, management history, and local climate, which we account for in the uncertainty analysis, 11,58 but warrants further in-depth study.…”

Section: Greenhouse Gas Footprint Of Biomass Sorghum Supply Systemmentioning

confidence: 99%

Supply Cost and Life-Cycle Greenhouse Gas Footprint of Dry and Ensiled Biomass Sorghum for Biofuel Production

Baral

Dahlberg

Putnam

et al. 2020

ACS Sustainable Chem. Eng.

Self Cite

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Biomass sorghum is a promising feedstock for cellulosic biorefineries because of its high yield and drought tolerance. However, the difficulty of effectively drying sorghum in some regions means it may require different handling than previously studied grassy feedstocks. This study compares the delivered cost and life-cycle greenhouse gas (GHG) footprint of field-drying and baling, module storage (wrapped, densely packed biomass), pelletizing, and ensiling. Ensiling has not been widely considered for use in bioenergy production. For farms within 66 km of the biorefinery, ensiled biomass is the lowest-cost and GHG strategy despite additional cost and energy demands for hauling wet biomass. Field-drying and baling, if feasible, is the most costeffective option for sorghum between 66 km and 104 km, beyond which pellets are preferable. A 2 2000 bone-dry-metric ton (bdt)/day biorefinery can source sorghum with 18 bdt/ha yield cultivated on 5% of surrounding land at costs range from $122 (silage) to $167 (pellets)/bdt and a life-cycle GHG footprint of 111 (silage) to 179 kg CO2e/bdt (pellets). With 28 bdt/ha biomass yield, 10% cultivation of surrounding land, and low fertilizer application, costs can range from $66 (silage) to $85 (pellets)/bdt and GHG footprint of 43 (silage) to 96 kg CO2e (pellets)/bdt.

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Sorghum biomass production in the continental United States and its potential impacts on soil organic carbon and nitrous oxide emissions

Cited by 30 publications

References 62 publications

Ecosystem‐scale biogeochemical fluxes from three bioenergy crop candidates: How energy sorghum compares to maize and miscanthus

Ecosystem‐scale biogeochemical fluxes from three bioenergy crop candidates: How energy sorghum compares to maize and miscanthus

Production Cost and Carbon Footprint of Biomass-Derived Dimethylcyclooctane as a High Performance Jet Fuel Blendstock

Supply Cost and Life-Cycle Greenhouse Gas Footprint of Dry and Ensiled Biomass Sorghum for Biofuel Production

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