Algae Biorefinery Development for Biofuels and Bioproducts Lieve Laurens

Bioenergy 2016 Washington, DC July 14, 2016 Algae-derived Commercial Products Reduce cost of algal biofuels: • Harness unique position of algae as highly efficient photosynthetic cell factories • Identify key targets to contribute to lowering the overall cost of algal biofuels production • Quantify impact of major components supporting a multi-product algal biorefinery model

• Analogous to replacing the whole barrel paradigm; low volume product streams can provide large fraction of value • Integrate biomass composition with cultivation and conversion performance 2 )

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Biomass production cost: $491/ton* l 35

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4 Algae Biorefinery Potential – high volume products

Biomass components wt % Product Market* (ton/yr) Fatty acids 10-45 Hydrocarbon fuel products (U.S. consumption) 16,000,000 8,000,000 – Omega-3-fatty acids 3-10 Polyols – epoxy resin – polyurethane 11,000,000 3-10 Nutraceuticals 22,000 Hydroxy-, branched-, fatty acids/alcohols ~1 Surfactants, fuel additives 3,500,000 Sterols 2-4 Surfactants 6,400,000 2-4 Phytosterol nutra-/pharmaceuticals 25,000 2-4 Emulsifiers N/A Phytol 3-4 Raw material for vitamin E, fragrance, soaps… 1 3-4 Surfactants, fuel additives 3,500,000 Polar lipids 10-35 Ethanolamine 600,000 Phosphatidylcholine, phosphoinositol and 10-35 20,000-30,000 phosphatidyl ethanolamine (lecithin ) Glycerol 2-6 Di-acids for nylon production 2,500,000 2-6 Feed, pharmaceuticals 25,000 Fermentable sugars (glucose, mannose) 10-45 Polylactic acid (PLA) polymers 300,000 10-45 Di-acids (e.g. succinic, muconic, adipic acid) 2,500,000 10-45 Ethanol 60,000,000 Mannitol 3-6 Polyether polyols 2,300,000¶ Alginate ~3-5 Alginate additives N/A Starch 5-40 Polysaccharide-derived bioplastics 2,000,000 Protein 19-40 Thermoplastics 5,000,000 Amino acids/peptides 19-20 Polyurethane 11,000,000 Amino acids/peptides 19-20 Biobutanol, mixed alcohol fuels 740,000 16,000,000 – Whole biomass 100 Animal/Fish feed 190,000,000 * Market size estimated based on displacement volumes ¶ based on sorbitol market size

5 5 Potential Options for co-Products

6 Algal Biorefinery Process

Fuels Only Solvent recovery Naphta CO2 Flocculant Nutrients Diesel Fresh/marine Jet wastewater DAF SLS * Upgrading Extrac on Dis lla on Water/Nutrient recycle AD **

Return CO2 Co-production of Fuels and Chemicals Ethanol Naphta Solvent recovery Flocculant Product Diesel purifica on Jet

DAF SLS Pretreatment Upgrading Fermenta on Extrac on Dis lla on Water/Nutrient recycle AD

Return CO2

Davis et al 2014: www.nrel.gov/docs/fy14osti/62368.pdf Laurens, L. et al., 2015, Green Chemistry, 2015, 17, 1145-1158 Dong, T., et al., 2016. Algal Research, doi:10.1016/j.algal.2015.12.021 NREL Pilot Plant

7 Algae Biorefinery

Ethanol • “Whole cell” fractionation after Naphta Solvent recovery acid pretreatmentFuel Only Flocculant Product Diesel purifica on • Techno-economic$19.80/GGEJet analysis (TEA) based on pilot scale data to show SLS DAF progress, cost reduction and Pretreatment Upgrading Fermenta on Extrac on Disllaon reduced risk AD Water/Nutrient recycle Fuel Yield + ethanol Return CO from sugars 2 Lipids (% DW) 27 $19.80/GGE Diesel Fuel Energy (103 btu/ton) 8,671 Fermentable Sugars (% DW) 48 Ethanol (gallon/ton) 79 Gasoline Fuel Energy (103 6,040 btu/ton) Combined Energy (103 btu/ton) 15,693 Davis et al 2014: www.nrel.gov/docs/fy14osti/62368.pdf Total Gasoline Gallon Equivalent Laurens, L. et al., 2015, Green Chemistry, 2015,135 17, 1145-1158 perDong, ton T., etbiomass al., 2016. (GGE/ton) Algal Research, doi:10.1016/j.algal.2015.12.021

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Figure ES-1. Economic summary for ALU pathway

v Value Proposition – Focus on co-Products

*Based on mid-harvest Scenedesmus biomass and IHS Chemical Economics Handbook, Epoxy Resins, May 2014 & demonstrated composition Surfactants, Household Detergents and their raw materials, June 2013 R. Davis (NREL) preliminary unpublished report

9 Summary

• Inclusion of co-products in algal biorefinery processes improves overall economics – 30% reduction in Fuel Selling Price • Value-added co-products are natively produced in photosynthetic algal cell factories • Novel products may support novel conversion process pathways including co-product development alongside fuels • Biomass composition drives conversion efficiency parameters and is highly linked with cultivation • Future R&D to support advanced algal systems economics based on the isolation and commercial harnessing of high-value, large market bioproducts and mapping over cultivation

10 Thank You! [email protected] Integration of Composition with Cultivation

Nannochloropsis ASU CalPoly TRL

Lipids (FAME) 60 Carbohydrates Protein ASU CalPoly Cellana ASU GT CalPoly TRL CellanaASU CGTalPoly CellanaTRL GT TRL 20 50

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Percent Percent WeightDry 10 5 6 6 30 6

10 EPA content(C20:5n3) 20 6

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Oct 15 Nov 01Nov 15 Dec 01 Oct 15 Nov 01Nov 15 Dec 01 Oct 15 Nov 01Nov 15 Dec 01 Low N Harvest Date

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