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TJ Lundquist, IC Woertz, NWT Quinn, JR Benemann (2010)
A realistic technology and engineering assessment of algae biofuel production
ME Huntley, DG Redalje (2007)
CO2 mitigation and renewable oil from photosynthetic microbes: a new appraisalMitig Adapt Strateg Glob Chang, 12
PJL Williams, LML Laurens (2010)
Microalgae as biodiesel & biomass feedstocks: review & analysis of the biochemistry, energetics & economicsEnergy Environ Sci, 3
KM Weyer, DR Bush, A Darzins, BD Willson (2009)
Theoretical maximum algal oil productionBioEnergy Res, 3
L Lardon, A Helias, B Sialve, JP Stayer, O Bernard (2009)
Life-cycle assessment of biodiesel production from microalgaeEnviron Sci Technol, 43
J Quinn, K Catton, N Wagner, T Bradley (2012)
Current large-scale us biofuel potential from microalgae cultivated in photobioreactorsBioEnergy Res, 5
ED Frank, J Han, I Palou-Rivera, A Elgowainy, MQ Wang (2011)
Life-cycle analysis of algal lipid fuels with the greet model
M Borowitzka (1992)
Algal biotechnology products and processes—matching science and economicsJ Appl Phycol, 4
Y Chisti (2007)
Biodiesel from microalgaeBiotechnol Adv, 25
PT Pienkos, A Darzins (2009)
The promise and challenges of microalgal-derived biofuelsBiofuels Bioprod Bioref-Biofpr, 3
R Pate, G Klise, B Wu (2011)
Resource demand implications for us algae biofuels production scale-upAppl Energy, 88
SC Doney (2011)
The growing human footprint on coastal and open-ocean biogeochemistryScience, 328
A Sun, R Davis, M Starbuck, A Ben-Amotz, R Pate, PT Pienkos (2011)
Comparative cost analysis of algal oil production for biofuelsEnergy, 36
L Batan, J Quinn, B Willson, T Bradley (2010)
Net energy and greenhouse gas emission evaluation of biodiesel derived from microalgaeEnviron Sci Technol, 44
Y Li, M Horsman, N Wu, CQ Lan, N Dubois-Calero (2008)
Biofuels from microalgaeBiotechnol Prog, 24
J Quinn, L Winter, T Bradley (2011)
Microalgae bulk growth model with application to industrial scale systemsBioresour Technol, 102
RH Wijffels, MJ Barbosa (2010)
An outlook on microalgal biofuelsScience, 329
SC James, V Boriah (2010)
Modeling algae growth in an open-channel racewayJ Comput Biol, 17
EM Grima, EH Belarbi, FGA Fernandez, AR Medina, Y Chisti (2003)
Recovery of microalgal biomass and metabolites: process options and economicsBiotechnol Adv, 20
PM Schenk, SR Thomas-Hall, E Stephens, UC Marx, JH Mussgnug, C Posten (2008)
Second generation biofuels: high-efficiency microalgae for biodiesel productionBioEnergy Res, 1
RA Kerr, E Kintisch (2010)
Climate change NRC reports strongly advocate action on global warmingScience, 328
PK Campbell, T Beer, D Batten (2011)
Life cycle assessment of biodiesel production from microalgae in pondsBioresour Technol, 102
JR Benemann (1996)
Oswald WJ (1996) Systems and economic analysis of microalgae ponds for conversion of CO2 to biomass
TM Mata, AA Martins, NS Caetano (2010)
Microalgae for biodiesel production and other applications: a reviewRenew Sust Energ Rev, 14
KE Trenberth (2010)
The climate fix what scientists and politicians won't tell you about global warmingScience, 330
J Sheehan, V Camobreco, J Duffield, M Graboski, H Shapouri (1998)
An overview of biodiesel and petroleum diesel life cycles
BSM Sturm, SL Lamer (2011)
An energy evaluation of coupling nutrient removal from wastewater with algal biomass productionAppl Energy, 88
SA Scott, MP Davey, JS Dennis, I Horst, CJ Howe, DJ Lea-Smith (2010)
Biodiesel from algae: challenges and prospectsCurr Opin Biotechnol, 21
R Davis, A Aden, PT Pienkos (2011)
Techno-economic analysis of autotrophic microalgae for fuel productionAppl Energy, 88
MS Wigmosta, AM Coleman, RJ Skaggs, MH Huesemann, LJ Lane (2011)
National microalgae biofuel production potential and resource demandWater Resour Res, 47
Previous assessments of the economic feasibility and large-scale productivity of microalgae biofuels have not considered the impacts of land and carbon dioxide (CO2) availability on the scalability of microalgae-based biofuels production. To accurately assess the near-term productivity potential of large-scale microalgae biofuel in the USA, a geographically realized growth model was used to simulate microalgae lipid yields based on meteorological data. The resulting lipid productivity potential of Nannochloropsis under large-scale cultivation is combined with land and CO2 resource availability illustrating current geographically feasible production sites and corresponding productivity in the USA. Baseline results show that CO2 transport constraints will limit US microalgae-based bio-oil production to 4 % of the 2030 Department of Energy (DOE) alternative fuel goal. The discussion focuses on synthesis of this large-scale productivity potential results including a sensitivity analysis to land and CO2 resource assumptions, an evaluation of previous modeling efforts, and their assumptions regarding the transportation of CO2, the feasibility of microalgae to meet DOE 2030 alternative fuel goals, and a comparison of the productivity potential in several key regions of the USA.
BioEnergy Research – Springer Journals
Published: Nov 20, 2012
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