Sourcing overseas biomass for EU ambitions: assessing net sustainable export potential from various sourcing countries

Mai-Moulin, Thuy; Fingerman, Kevin; Elbersen, Wolter; Elbersen, B.S.; Nabuurs, Gert‐Jan; Fritsche, Uwe R.; Colmenar, Inés Del Campo; Rutz, Dominik; Díaz‐Chavez, Rocío; Roozen, A.M.P.; Weck, M.H.J.; Iriarte, Liliana; Pelkmans, Luc; González, David Sánchez; Janssen, Rainer; Junginger, Martin

doi:10.1002/bbb.1853

Cited by 26 publications

(26 citation statements)

References 44 publications

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“…Other European regions, especially the Baltic countries, also supply these four markets, but with a smaller quantity. 28,35 Figure 7 also shows a record of wood pellets with sustainability claims in 2016 with 6.5 Tg imported to the UK, 2.6 Tg to Belgium and 0.7 Tg to Denmark. In the Netherlands, the import decreased in 2014 and was negligible in 2015 and 2016 due to lack of a Stimulation of Sustainable Energy Production budget.…”

Section: Development Of Trade Flows With Proof Of Sustainabilitymentioning

confidence: 99%

The dynamics of the global wood pellet markets and trade – key regions, developments and impact factors

Thrän

Schaubach

Peetz

et al. 2018

Biofuels Bioprod Bioref

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The global pellet market is growing but with different characteristics in different countries and regions. In this paper we trace developments between 2008 and 2016. For 2008, production was reported at 9.8 Tg, expanding globally to 14.3 Tg in 2010 and surpassing 26 Tg in 2015. Global hot spots are North America (production) and Europe (consumption). Sustainability certification was applied for about 9 Tg in 2016. Nevertheless, projections for future development are difficult as low pellet prices and uncertain sustainability obligations may hinder further expansion. In general, there is a strong dependency of the pellet market on the policy framework. © 2018 The Authors. Biofuels, Bioproducts, and Biorefining published by Society of Chemical Industry and John Wiley & Sons, Ltd.

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Section: Development Of Trade Flows With Proof Of Sustainabilitymentioning

confidence: 99%

The dynamics of the global wood pellet markets and trade – key regions, developments and impact factors

Thrän

Schaubach

Peetz

et al. 2018

Biofuels Bioprod Bioref

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“…Various studies have quantified the future domestic biomass supply potential; however, its mobilization depends on a magnitude of social, technical, and economic factors (Creutzig et al., ). Extra‐EU import potentials are possibly large, but depend on mobilization efforts and domestic consumption in the exporting countries (Mai‐Moulin et al., ). This study attempts to capture this variation in a Low Biomass Supply (LS) and High Biomass Supply (HS) scenario.…”

Section: Methodsmentioning

confidence: 99%

Renewable jet fuel supply scenarios in the European Union in 2021–2030 in the context of proposed biofuel policy and competing biomass demand

et al. 2018

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This study presents supply scenarios of nonfood renewable jet fuel (RJF) in the European Union (EU) toward 2030, based on the anticipated regulatory context, availability of biomass and conversion technologies, and competing biomass demand from other sectors (i.e., transport, heat, power, and chemicals). A cost optimization model was used to identify preconditions for increased RJF production and the associated emission reductions, costs, and impact on competing sectors. Model scenarios show nonfood RJF supply could increase from 1 PJ in 2021 to 165–261 PJ/year (3.8–6.1 million tonne (Mt)/year) by 2030, provided advanced biofuel technologies are developed and adequate (policy) incentives are present. This supply corresponds to 6%–9% of jet fuel consumption and 28%–41% of total nonfood biofuel consumption in the EU. These results are driven by proposed policy incentives and a relatively high fossil jet fuel price compared to other fossil fuels. RJF reduces aviation‐related combustion emission by 12–19 Mt/year CO2‐eq by 2030, offsetting 53%–84% of projected emission growth of the sector in the EU relative to 2020. Increased RJF supply mainly affects nonfood biofuel use in road transport, which remained relatively constant during 2021–2030. The cost differential of RJF relative to fossil jet fuel declines from 40 €/GJ (1,740 €/t) in 2021 to 7–13 €/GJ (280–540 €/t) in 2030, because of the introduction of advanced biofuel technologies, technological learning, increased fossil jet fuel prices, and reduced feedstock costs. The cumulative additional costs of RJF equal €7.7–11 billion over 2021–2030 or €1.0–1.4 per departing passenger (intra‐EU) when allocated to the aviation sector. By 2030, 109–213 PJ/year (2.5–4.9 Mt/year) RJF is produced from lignocellulosic biomass using technologies which are currently not yet commercialized. Hence, (policy) mechanisms that expedite technology development are cardinal to the feasibility and affordability of increasing RJF production.

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“…This trade stream, driven by European demand, has increased almost ten times in the last seven years (2) In Europe, the Baltic states' wood exports have recently developed and this area is expected to play an important role in the biomass trade sector . (3) Recently, sugarcane bagasse pellets from São Paulo state (Brazil) are considered to have a high export potential, which meets economic, social, and sustainability criteria . A domestic sugar beets supply stream was also considered for comparison purposes (domestic sourced sugar crops versus internationally sourced lignocellulosic biomass).…”

Section: Introductionmentioning

confidence: 99%

“…38 (3) Recently, sugarcane bagasse pellets from São Paulo state (Brazil) are considered to have a high export potential, which meets economic, social, and sustainability criteria. 39 A domestic sugar beets supply stream was also considered for comparison purposes (domestic sourced sugar crops versus internationally sourced lignocellulosic biomass). This crop type is considered relevant for different applications, as in bio-based materials, for the country's bio-based economy transition.…”

Section: Introductionmentioning

confidence: 99%

A carbon footprint assessment of multi‐output biorefineries with international biomass supply: a case study for the Netherlands

Vera

Hoefnagels

Kooij³

et al. 2019

Biofuels Bioprod Bioref

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The efficient use of lignocellulosic biomass for the production of advanced fuels and bio‐based materials has become increasingly relevant. In the EU, regulatory developments are stimulating the mobilization and production of bio‐based chemicals / materials and biofuels from lignocellulosic biomass. We used an attributional life‐cycle assessment approach based on region‐specific characteristics to determine the greenhouse gas emissions (GHG) performance of different supply‐chain configurations with internationally sourced lignocellulosic biomass (stem wood, forest residues, sawmill residues, and sugarcane bagasse) from the USA, the Baltic States (BS), and Brazil (BR) for the simultaneous production of lactide and ethanol in a biorefinery located in the Netherlands (NL). The results are compared with a biorefinery that uses locally cultivated sugar beets. We also compared GHG emissions savings from the supply‐chain configurations with the minimum GHG saving requirements in the revised Renewable Energy Directive (RED II) and relevant fossil‐based counterparts for bio‐based materials. The GHG emissions ‘from cradle to factory gate’ vary between 692 g CO2eq/kglactide (sawmill residues pellets from the BS) and 1002 g CO2eq/kglactide (sawmill chips from the USA) for lactide and between 15 g CO2eq/MJethanol (sawmill residues pellets from the BS) and 28 g CO2eq/MJethanol (bagasse pellets from BR) for ethanol. Upstream GHG emissions from the conversion routes have a relatively small impact compared with biomass conversion to lactide and ethanol. The use of woody biomass yields better GHG emissions performance for the conversion system than sugarcane bagasse or sugar beets as result of the higher lignin content that is used to generate electricity and heat internally for the system. Only the sugar beet from the NL production route is able to comply with RED II GHG savings criteria (65% by 2021). The GHG savings from polylactide acid (a derivate of lactic acid) are high and vary depending on choice of fossil‐based counterpart, with the highest savings reported when compared to polystyrene (PS). These high savings are mostly attributed to the negative emission credit from the embedded carbon in the materials. Several improvement options along the conversion routes were explored. Efficient feedstock supply chains (including pelletization and large ocean vessels) also allow for long‐distance transportation of biomass and conversion in large‐scale biorefineries close to demand centers with similar GHG performance to biorefineries with a local biomass supply. © 2019 The Authors. Biofuels, Bioproducts, and Biorefining published by Society of Chemical Industry and John Wiley & Sons, Ltd.

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Sourcing overseas biomass for EU ambitions: assessing net sustainable export potential from various sourcing countries

Cited by 26 publications

References 44 publications

The dynamics of the global wood pellet markets and trade – key regions, developments and impact factors

The dynamics of the global wood pellet markets and trade – key regions, developments and impact factors

Renewable jet fuel supply scenarios in the European Union in 2021–2030 in the context of proposed biofuel policy and competing biomass demand

A carbon footprint assessment of multi‐output biorefineries with international biomass supply: a case study for the Netherlands

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