1. AAFC-NRCan-NRC National Bioproducts Program Chemical and ethanol production from lignocellulosic materials IRAP TechnoBusiness Meeting, January 13, 2009 John Schmidt, Serge Laberge co-Project Lead Directors

2. Outline National Bioproducts Program – What is it? Chemicals and ethanol from lignocellulosic materials – project description Current status

3. National Bioproducts Program Joint initiative of National Research Council, Agriculture & Agrifood Canada, Natural Resources Canada Unite university, government and industry scientists to develop bioproducts/biofuels technology for Canada Four project areas: –Chemical and ethanol production from lignocellulosic materials –Biomaterials and biopolyols for automotive, aerospace, construction and plastics industries –Fuels and chemicals from anaerobic digestion or gasification of municipal solid waste and/or biomass –Biodiesel from marine algae

4. National Bioproducts Program – project criteria Objective: Commercializable technologies within 3 – 5 years that address Canadian priorities in sustainable energy, environment and rural revitalization From the outset, at least one industrial partner who can receive the technology; i.e., market pull rather than technology push More than one participant Will stand up to life-cycle assessment

5. Chemicals and ethanol from lignocellulosic materials - Two lignocellulose value chains Forestry (chemical pulp mills) –Cellulose most valuable for pulp ($800/t) –Chemicals/fuels from lignin and hemicellulose Agricultural residues and other wood –Fractionate biomass to separate lignin from cellulose –Two uses for cellulose: Fibres for biomaterials (e.g. flax) Ethanol via thermal or biological conversion –Lignin and hemicellulose to chemicals –Pyrolysis – bio-oil and char

6. Lignin activities Interesting opportunities identified based on price, volume and market stability: Substitute for phenol ($1500/t) in phenol-formaldehyde resins (FPInnovations, BRI) Substitute for carbon black ($2000/t) in tires (FPInnovations, Lakehead University (Prof. A. Chen), BRI) Carbon fibre – currently made from polyacrylonitrile ($3,000/t) (FPInnovations, University of British Columbia (Prof. J. Kadla)) Single-walled carbon nanotubes (SWCNT) from pyrolysis chars and use of the SWCNTs in the above applications (SIMS, above researchers, also biomaterials and gasification projects)

7. Hemicellulose Hemicellulose from wood prehydrolysis, mild acid treatment of agricultural residues –Furfural – maximum 50% yield from acidolysis of xylose –5-Hydroxymethylfurfural (HMF) – from 6-carbon sugars Nanocatalysis to improve yields of furfural and HMF –Nanocatalytic transformation of HMF to 2,5- furandicarboxylic acid FPInnovations and a member company, BRI

8. Cellulosic ethanol Biomass fractionation: –Physical/chemical methods (Dr. J. Hawari, BRI) microwave/ultrasound techniques to accelerate chemical separation of lignin from cellulose –Enzymatic methods (Dr. Peter Lau, BRI) Feruloyl esterase, cutinase (alfalfa, triticale) Aromatic chemicals derived from lignin, e.g.ferulic acid, vinyl guaiacol, vanillin Cellulose degradation: –Hyperthermophilic cellulases (Dr. W. Sung, IBS, S. Laberge, J. Simmonds, A. Laroche, AAFC) Pentose fermentation: –Genetic manipulation of S. cerevisiae to improve xylose uptake and fermentation (Dr. M. Whiteway, BRI)

9. Summary of value chains and activities Biomass Fractionation (bioconversion, pyrolysis, microwave or ultrasound) Lignin Hemicellulose Cellulose Increased furfural yield HMF Furandicarboxylic acid PF resins, carbon fibre SWCNT, bio-oil Lignin in tires Aromatic acids Pentose fermentation Hyperthermophilic cellulases Fuel

10. Status Still actively seeking industrial participants who can contribute to project objectives and develop the technologies to full commercial scale Advisory Board meeting on December 5 –General comment to focus on fewer activities –Development of business cases to determine most promising objectives

11. Thank you for your attention! John.schmidt@fpinnovations.ca