Acid-catalyzed algal biomass pretreatment for integrated lipid and carbohydrate-based biofuels production

One of the major challenges associated with algal biofuels production in a biorefinery-type setting is improving biomass utilization in its entirety, increasing the process energetic yields and providing economically viable and scalable co-product concepts. We demonstrate the effectiveness of a novel, integrated technology based on moderate temperatures and low pH to convert the carbohydrates in wet algal biomass to soluble sugars for fermentation, while making lipids more accessible for downstream extraction and leaving a protein-enriched fraction behind. We studied the effect of harvest timing on the conversion yields, using two algal strains; Chlorella and Scenedesmus, generating biomass with distinctive compositional ratios of protein, carbohydrate, and lipids. We found that the late harvest Scenedesmus biomass had the maximum theoretical biofuel potential at 143 gasoline gallon equivalent (GGE) combined fuel yield per dry ton biomass, followed by late harvest Chlorella at 128 GGE per ton. Our experimental data show a clear difference between the two strains, as Scenedesmus was more successfully converted in this process with a demonstrated 97 GGE per ton. Our measurements indicated a release of >90% of the available glucose in the hydrolysate liquors and an extraction and recovery of up to 97% of the fatty acids from wet biomass. Techno-economic analysis for the combined product yields indicates that this process exhibits the potential to improve per-gallon fuel costs by up to 33% compared to a lipids-only process for one strain, Scenedesmus, grown to the mid-point harvest condition.

[1]  L. Laurens,et al.  Determination of Total Lipids as Fatty Acid Methyl Esters (FAME) by in situ Transesterification: Laboratory Analytical Procedure (LAP) , 2013 .

[2]  F. García-Camacho,et al.  Biomass nutrient profiles of the microalga Nannochloropsis. , 2001, Journal of agricultural and food chemistry.

[3]  R. Elander,et al.  High Xylose Yields from Dilute Acid Pretreatment of Corn Stover Under Process-Relevant Conditions , 2009, Applied biochemistry and biotechnology.

[4]  D. Allen,et al.  Energy-water nexus for mass cultivation of algae. , 2011, Environmental science & technology.

[5]  J. R. Hess,et al.  Process Design and Economics for Conversion of Lignocellulosic Biomass to Ethanol: Thermochemical Pathway by Indirect Gasification and Mixed Alcohol Synthesis , 2011 .

[6]  Richard T Elander,et al.  Characterization of pilot-scale dilute acid pretreatment performance using deacetylated corn stover , 2014, Biotechnology for Biofuels.

[7]  Susanne B. Jones,et al.  Integrated evaluation of cost, emissions, and resource potential for algal biofuels at the national scale. , 2014, Environmental science & technology.

[8]  Mark A. White,et al.  Environmental impacts of algae-derived biodiesel and bioelectricity for transportation. , 2011, Environmental science & technology.

[9]  Shu-wen Huang,et al.  Bioethanol production using carbohydrate-rich microalgae biomass as feedstock. , 2013, Bioresource technology.

[10]  Andre M. Coleman,et al.  Renewable Diesel from Algal Lipids: An Integrated Baseline for Cost, Emissions, and Resource Potential from a Harmonized Model , 2012 .

[11]  Michael E. Salassi,et al.  economic feasibility of ethanol production from sugar in the United States , 2006 .

[12]  Julie B. Zimmerman,et al.  ALGAE AS A SOURCE OF RENEWABLE CHEMICALS: OPPORTUNITIES AND CHALLENGES , 2011 .

[13]  J. O. Baker,et al.  Genomic, Proteomic, and Biochemical Analyses of Oleaginous Mucor circinelloides: Evaluating Its Capability in Utilizing Cellulolytic Substrates for Lipid Production , 2013, PloS one.

[14]  L. Laurens,et al.  Determination of Total Solids and Ash in Algal Biomass: Laboratory Analytical Procedure (LAP) , 2013 .

[15]  R. Helm,et al.  Identification of inhibitory components toxic toward zymomonas mobilis CP4(pZB5) xylose fermentation , 1997 .

[16]  M. Eppink,et al.  Microalgae for the production of bulk chemicals and biofuels , 2010 .

[17]  Eric C. D. Tan,et al.  Process Design and Economics for the Conversion of Lignocellulosic Biomass to Hydrocarbons: Dilute-Acid and Enzymatic Deconstruction of Biomass to Sugars and Biological Conversion of Sugars to Hydrocarbons , 2013 .

[18]  Julie Zimmerman,et al.  Design Through the 12 Principles of Green Engineering , 2003, IEEE Engineering Management Review.

[19]  Thomas H. Bradley,et al.  Current Large-Scale US Biofuel Potential from Microalgae Cultivated in Photobioreactors , 2012, BioEnergy Research.

[20]  Rodrigo E. Teixeira Energy-efficient extraction of fuel and chemical feedstocks from algae , 2012 .

[21]  J Swings,et al.  The biology of Zymomonas , 1977, Bacteriological reviews.

[22]  Q. Hu,et al.  Microalgal triacylglycerols as feedstocks for biofuel production: perspectives and advances. , 2008, The Plant journal : for cell and molecular biology.

[23]  Edward J. Wolfrum,et al.  Accurate and reliable quantification of total microalgal fuel potential as fatty acid methyl esters by in situ transesterification , 2012, Analytical and Bioanalytical Chemistry.

[24]  Peter E. Zemke,et al.  Assessment of key biological and engineering design parameters for production of Chlorella zofingiensis (Chlorophyceae) in outdoor photobioreactors , 2013, Applied Microbiology and Biotechnology.

[25]  Eun Yeol Lee,et al.  Chemo-enzymatic saccharification and bioethanol fermentation of lipid-extracted residual biomass of the microalga, Dunaliella tertiolecta. , 2013, Bioresource technology.

[26]  Roy W Harris,et al.  Process Design and Cost Estimating Algorithms for the Computer Assisted Procedure for Design and Evaluation of Wastewater Treatment Systems (CAPDET). , 1982 .

[27]  Edward J. Wolfrum,et al.  Compositional Analysis of Lignocellulosic Feedstocks. 2. Method Uncertainties , 2010, Journal of agricultural and food chemistry.

[28]  Q. Hu,et al.  A flexible culture process for production of the green microalga Scenedesmus dimorphus rich in protein, carbohydrate or lipid. , 2013, Bioresource technology.

[29]  L. Gouveia,et al.  Pre-treatment optimization of Scenedesmus obliquus microalga for bioethanol production. , 2012, Bioresource technology.

[30]  Andrew J. Schmidt,et al.  Process development for hydrothermal liquefaction of algae feedstocks in a continuous-flow reactor , 2013 .

[31]  Razif Harun,et al.  Microalgal biomass as a fermentation feedstock for bioethanol production , 2009 .

[32]  Bärbel Hahn-Hägerdal,et al.  Fermentation of lignocellulosic hydrolysates. II: inhibitors and mechanisms of inhibition. , 2000 .

[33]  Ryan Davis,et al.  Techno-economic analysis of autotrophic microalgae for fuel production , 2011 .

[34]  L. Laurens,et al.  Separation and quantification of microalgal carbohydrates. , 2012, Journal of chromatography. A.

[35]  T. G. Villa,et al.  Oily yeasts as oleaginous cell factories , 2011, Applied Microbiology and Biotechnology.

[36]  P. Biller,et al.  Potential yields and properties of oil from the hydrothermal liquefaction of microalgae with different biochemical content. , 2011, Bioresource technology.

[37]  Yung-Tse Hung,et al.  Biosolids Treatment Processes , 2007 .

[38]  G. Charles Dismukes,et al.  Increased Lipid Accumulation in the Chlamydomonas reinhardtiista7-10 Starchless Isoamylase Mutant and Increased Carbohydrate Synthesis in Complemented Strains , 2010, Eukaryotic Cell.

[39]  Philip T Pienkos,et al.  Strain, biochemistry, and cultivation-dependent measurement variability of algal biomass composition. , 2014, Analytical biochemistry.

[40]  L. Laurens Summative Mass Analysis of Algal Biomass - Integration of Analytical Procedures: Laboratory Analytical Procedure (LAP) , 2016 .

[41]  Navid R. Moheimani,et al.  Microalgal biomass for bioethanol fermentation: Implications for hypersaline systems with an industrial focus , 2012 .

[42]  Razif Harun,et al.  Influence of acid pre-treatment on microalgal biomass for bioethanol production , 2011 .

[43]  D. Block,et al.  Oleaginous yeasts for biodiesel: current and future trends in biology and production. , 2014, Biotechnology advances.

[44]  J. R. Hess,et al.  Process Design and Economics for Conversion of Lignocellulosic Biomass to Ethanol , 2011 .

[45]  Roland Span,et al.  Anaerobic co-digestion of the marine microalga Nannochloropsis salina with energy crops. , 2013, Bioresource technology.

[46]  J. Mossé Nitrogen-to-protein conversion factor for ten cereals and six legumes or oilseeds. A reappraisal of its definition and determination. Variation according to species and to seed protein content , 1990 .

[47]  Arnaud Hélias,et al.  Life-cycle assessment of biodiesel production from microalgae. , 2009, Environmental science & technology.

[48]  Ryan Davis,et al.  Process Design and Economics for Biochemical Conversion of Lignocellulosic Biomass to Ethanol: Dilute-Acid Pretreatment and Enzymatic Hydrolysis of Corn Stover , 2011 .

[49]  L. Laurens,et al.  Determination of Total Carbohydrates in Algal Biomass: Laboratory Analytical Procedure (LAP) , 2013 .

[50]  Charles E. Wyman,et al.  Thermotolerant yeast for simultaneous saccharification and fermentation of cellulose to ethanol , 1988 .

[51]  Min Zhang,et al.  Metabolic Engineering of a Pentose Metabolism Pathway in Ethanologenic Zymomonas mobilis , 1995, Science.

[52]  N. Dowe Assessing cellulase performance on pretreated lignocellulosic biomass using saccharification and fermentation-based protocols. , 2009, Methods in molecular biology.

[53]  Havva Balat,et al.  Recent trends in global production and utilization of bio-ethanol fuel , 2009 .

[54]  Minghan Zhu,et al.  Hydrothermal reaction kinetics and pathways of phenylalanine alone and in binary mixtures. , 2012, ChemSusChem.

[55]  L. Laurens,et al.  Microalgae as biodiesel & biomass feedstocks: Review & analysis of the biochemistry, energetics & economics , 2010 .