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Global Alternative Biofuel Technology Strategies Sergio C. Trindade strindade@alum.mit.edu

Global Alternative Biofuel Technology Strategies Sergio C. Trindade strindade@alum.mit.edu. Shanghai Association for Science and Technology Shanghai Municipal Science and Technology Commission Shanghai, 15 October 2008

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Global Alternative Biofuel Technology Strategies Sergio C. Trindade strindade@alum.mit.edu

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  1. Global Alternative Biofuel Technology StrategiesSergio C. Trindadestrindade@alum.mit.edu Shanghai Association for Science and Technology Shanghai Municipal Science and Technology Commission Shanghai, 15 October 2008 Based on Trindade, Sergio C. “Global Biofuels Picture and the Prospects for International Trade” and Larson, Eric, “Biofuel Production Technologies: Status and Prospects”. UNCTAD Ad hoc expert group meeting on Biofuels: Trade and Development Implications of Present and Emerging Technologies, 19 June 2007, Geneva

  2. Global Alternative Biofuel Technology Strategies • Major drivers for promoting alternative biofuels • Measures and results • Which direction in the next five years?

  3. The Beginning of a New Era % We are here today Solar Source: Nakícenovic, Grübler and MaConald, 1998

  4. The Energy Menu • Since coal began to replace wood as an energy source, energy needs met by a combination of sources • The menu today is dominated by oil, but soon natural gas will take over • Coal remains important especially in large countries such as China, the US and India • Biomass and other renewables and nuclear are the remaining sources. • Biofuels have a role to play in stretching the life of the world’s current energy supply. • Cannot be expected to replace the totality of the liquid fossil fuels supplies at any point in time • Will however play a role in the transition towards the long term energy future

  5. Source: Towler, Gavin P. Anil R. Oroskar and Suzanne E. Smith (2003). “Development of a Sustainable Liquid Fuels Infrastructure Based on Biomass”.Environmental Progress, vol. 23, issue 4, pp. 334-341

  6. Measures and results • Promotion of national biofuels programs via mandates and financial incentives in Brazil, US, EU, China, Thailand, Philippines, India, Colombia, Mexico, Argentina • Fuel ethanol penetrated up to 50% of the gasoline market (Brazil), 5% in the US • Biodiesel achieved more modest results

  7. Which direction in the next five years? • Limits to food crop based biofuels • Saturation of first generation biofuels • Switch to second generation biofuels, based on cellulosic feedstocks • Competition between biochemical and thermochemical second generation proceses • Transportation, power and cooking fuel markets

  8. Biofuel Classification First Generation (from sugars, grains, or seeds) • Biodiesel (fatty acid methyl or ethyl ester) • rapeseed (RME), soybeans (SME), sunflowers, jatropha, coconut, palm, recycled cooking oil • Pure plant oils (straight vegetable oil). • Alcohols (ethanol, butanol) • From grains or seeds: corn, wheat, potato • From sugar crops: sugar beets, sugarcane

  9. Biofuel Classification Second Generation (from lignocellulose: crop residues, grasses, woody crops) • Biological conversion • Ethanol (or butanol) via enzymatic hydrolysis • Thermochemical conversion (most made via “gasification”) • Fischer-Tropsch liquids (FTL) • Methanol, MTBE, gasoline • Dimethyl ether (DME) • Mixed alcohols • Green diesel

  10. Corn

  11. Veg. Oils and Biodiesel: Raw Materials and Markets

  12. Biofuels Oil Products Ethanol Gasoline Ethanol Butanol Butanol Diesel Mixed Alcohols LPG Methanol Fischer Tropsch Paraffin Biodiesel Kerosene Diesel Green diesel Dimethyl ether Biocrude Crude oil First Generation Second Generation

  13. Biofuel Cooking Fuel cleanest options Ethanol Alcohol Gel Methanol LPG Mix. Alcohols DME DME Paraffin FTL Kerosene • Three billion people on earth cook with solid fuels today. • Indoor air pollution from cooking as 2nd highest environmental risk factor (after unsanitary water) to global burden of disease (WHO: 1.6 million premature deaths/yr) • 4 to 5 EJ/yr of biofuel [~35 kg/cap/yr LPGequiv] is sufficient to “solve” this problem. (This is ~1% of global commercial energy use today).

  14. 1st Generation Fuel Ethanol Production

  15. U.S. Corn Ethanol Production27% of 2007 corn  34 billion liters (<4% of gasoline demand)

  16. 1st Generation Ethanol Costs(feedstock is largest component) Source: Assis, V., Elstrodt, H-P., and Silva, C.F.C., “Positioning Brazil for Biofuels Success,” The McKinsey Quarterly, special edition on Shaping a New Agenda for Latin America, 2007.

  17. Prices paid to ethanol producers Ethanol price trend line Rotterdam regular gasoline price Rotterdam gasoline price trend Learning Curve of Ethanol in Brazil (2004) US$ per GJ of Ethanol Cumulative Production of Ethanol (thousand m3) Source: Nastari, P.M. "Competitividade da Produção de Etanol de Cana-de-açúcar no Brasil: as três ondas de desenvolvimento", V Conferência Internacional da Datagro sobre Açúcar e Álcool, Grand Hyatt São Paulo, 20 de setembro de 2005, São Paulo, SP.

  18. Brazil Experience is Widely Relevant Source: As cited in Coelho, S.,“Brazilian Sugarcane Ethanol: Lessons Learned,” Energy for Sustainable Development, X(2): 26-39, 2006.

  19. First Generation Biofuels • Limitations of sugar or starch crops: • Competition for food uses • Plants optimized for food, not energy • Only part of the plant is converted to biofuel • Co-product sales key for acceptable economics • Only modest energy and GHG benefits, except with sugarcane ethanol (due to greater utilization of the above-ground biomass)

  20. First Generation Biofuels • Can blend with existing petroleum-derived motor fuels – minimal infrastructure change • Large-scale experience in Brazil and USA • Relatively high costs (except sugarcane ethanol in Brazil) due to high feedstock cost • Cost penalties less severe at smaller scales

  21. Second Generation Biofuels • Made from lignocellulosic materials • Biomass that is generally not edible • Larger fraction of the plant is converted to fuel • Plants can be bred for energy characteristics (high yield, low inputs) • Two generic processing routes: biological or thermochemical (also hybrid combination)

  22. Second Generation Biofuels • Can blend with petroleum fuels in most cases • Substantial energy/environment benefits compared with most 1st generation biofuels due primarily to greater biomass useability per unit land area • Greater capital-intensity than 1st generation biofuels, but lower feedstock costs  higher cost-scale sensitivity.  larger scale facilities needed for optimum economics

  23. Yields for Different Biomass Types

  24. 2nd Generation: Cost vs Scale Total economic optimum Capital Biomass

  25. 2nd Generation Ethanol Processes (similar routes for butanol) Raw Biomass Combining of two steps proposed: simultaneous saccharification and fermentation – SSF Ethanol Pretreatment Recovery & Distillation Saccharification Fermentation Enzyme production Steam and power generation Combining of three steps proposed: consolidated bioprocessing – CBP Solids separation Process steam/elec.

  26. Cost Targets For Cellulosic Ethanol United States’ National Renewable Energy Lab For direct comparison with gasoline price per gallon, multiply ethanol price per gallon by 1.6 $30/t biomass cost in long term is probably unrealistically low for large-scale, sustainable biomass supply in the USA, but not in many developing countries.

  27. 2nd Generation: Biological • “Cellulosic ethanol” (cellulosic biobutanol) • Limited fraction of the biomass can be converted with known enzymatic technology today • Lignin not convertible in any case, but can use for heat or co-product.

  28. 2nd Generation: Biological • Limited feedstock flexibility – micro-organisms must be tailored to the feedstock • R&D breakthroughs needed to improve conversion and reduce costs • Production costs may be less scale sensitive than for thermochemical fuels

  29. 2nd Generation Thermochemical Raw Biomass oxygen Biofuel Drying Sizing Gasification Distillation or Refining Synthesis Gas cleaning Steam and Power Generation Process steam/elec. (+ export electricity) Water Gas Shift (CO+H2O  H2+CO2) CO + H2 + CH4 CO2 Removal Alcohols Distillation or Refining Fermentation Steam and Power Generation Process steam/elec. (+ export electricity)

  30. Gasification Capacity by Feedstock Global Gasification Capacity

  31. China coal-based DME production(for LPG and diesel bus markets)

  32. 2nd Generation: Thermochemical • Full utilization of biomass, accommodates wide range of feedstocks • Conversion technologies available today for FTL, DME, MeOH – no R&D breakthroughs needed. • For ethanol or butanol (by fermentation of syngas), further research on micro-organisms. • With biomass costing $3-5/GJ ($54-90/dry t) – in OECD – FTL would be competitive for oil at $70*-90**/bbl with known technology • Lower biomass costs in developing countries and “learning-by-doing” (Brazil ethanol program), will make thermochemical fuels competitive at much lower oil prices • Commercial-scale implementation of large-scale biomass gasification systems are lacking today, but large overlap (and synergies) with commercially established fossil fuel conversion technologies, so practical experience base already exists. * Larson, Williams, Jin, paper at 8th International Conference on Greenhouse Gas Control Technologies, June 2006. ** van Ree, van der Drift, Zwart, Boerigter, presented at the First International Biorefinery Workshop, Washington DC, July 2005.

  33. Biofuel Production Pathways DME CNG, LNG FTL MeOH Mixed OH Ethanol Biodiesel Green Diesel LPG Petrol Diesel Blending Synthesis Esterification Refining Refining Hydro- Thermal Upgrading Gasification Pyrolysis Fermentation Extraction Refining Hydrolysis Anaerobic Digestion (Biogas) Lignocellulosic biomass Sugar and starch crops Oil crops Wet biomass Natural gas Coal Crude oil FOSSIL FUELS BIOMASS “Second” Generation First Generation • (Biomass can be co-gasified with coal for thermochemical fuels production)

  34. Comparing Energy Balances (also, roughly, 1st generation sugarcane ethanol)

  35. Summary • Potential of 1st or 2nd generation biofuels to • Replace fair share of transport fuels use in most developing countries (given low per-capita transport-sector fuel use today). • Provide cleaner cooking fuels for all households by replacing solid fuels. • Sugarcane ethanol, plus most 2nd generation biofuels, will significantly reduce GHG emissions per unit of transportation service provided. Other first generation biofuels have only modest GHG reduction potential. • Economics of 1st gen. biofuels (other than cane-ethanol): • In the N countries, subsidies (or oil price at least $50-$60/bbl) needed for competitiveness, even for large-scale facilities, due primarily to the use of (expensive) food crops as the feedstock. • In the S countries, economics unlikely to be much better than in the North, despite lower labor costs, due to lower agricultural productivities, global markets for commodity crops, and generally smaller scales of biofuel production facilities.

  36. Summary Second generation biofuels • Under development primarily in the N. Further R,D&D needed to improve economics. • Time to commercial readiness: 10-20 years for cellulosic ethanol; ½ or less of this for thermochemical fuels. • Both biological and thermochemical require larger scales (with dedicated biomass) than most 1st generation processes • Higher investment costs per unit production than 1st generation fuels, but lower feedstock costs  lower total costs • Key intellectual property elements: 1) micro-organisms for biological conversion 2) catalysts for thermochemical conversion.

  37. Trade/Development Implications • Potential land use conflicts for food vs. biofuel may be mitigated by: a) increasing productivity of food agriculture (yield/ha) – large gains are possible; b) targeting biofuel feedstock production on marginal c) targeting the production of 2nd generation biofuels to maximize land-use efficiency. • Economics of 2nd generation biofuels in the S have the potential to be much better than in the N • S countries have comparative cost advantages in producing feedstocks (better climates, lower labor costs, and lower land costs)

  38. Trade/Development Implications • Large global markets for biofuels will continue to grow in the N based on mandates and high oil prices • Significant export opportunities for biofuels or biofuel feedstocks from S to N may materialize • CDM credit may improve biofuel economics. • Competitive exports based on low feedstock and labor costs, the S must promote world-class scales and efficiencies, and low capital investment intensity • Sustainable domestic demand (e.g. via mandates) could be an important first step (Brazilian model)

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