5^th World Bioenergy Congress and Expo

Biography

Biography: Patricia J Harvey

Abstract

Statement of the problem: Global energy consumption will grow by up to 50% by 2035; 60% more food will be needed and global water use for irrigation could increase by 10% by 2050. Glycerol, a new biofuel and by-product of biodiesel manufacture, is planned to be combusted using new engine technology (410kW electrical; 450kW thermal) to provide heat and power at the University of Greenwich UK, provided sufficient reliable supplies of glycerol can be sourced at the right specification. Biofuels, however, can necessitate substantial water inputs depending on feedstock production: by 2030, the global blue biofuel water footprint might have grown to 5.5% of the totally available blue water for humans, causing extra pressure on fresh water resources. Methodology & Theoretical Orientation: The blue water footprint of the net energy provided by microalgal biofuels has been concluded to be significantly smaller compared with fuels from other energy crops. Extremophile, halotolerant microalgae such as Dunaliella produce glycerol without the requirement to process lipids to release the glycerol. The potential for commercial glycerol production from Dunaliella is examined in the D-Factory, a €10m, 14-partner, FP7-funded project (2013-2017).

Findings: Dunaliella can be cultivated at large-scale in hypersaline water using solar energy and with minimal fresh water and flue-gas CO2.  These algae can be processed for glycerol and a range of high-value products for disease mitigation, and biomass can be used in new food products and in feedstuffs. A demonstration is underway to show the potential for commercialization of algae such as Dunaliella.  From this work, the scope to produce commodities such as glycerol from algae is discussed in the context of the water-food-energy nexus and circular economy.

Conclusion & Significance: Awareness of the water-food-energy nexus offers opportunities to utilize algae sustainably for the production of biobased products. 

Recent Publications:

1. FAO (2014) The Water-Energy-Food Nexus: A new approach in support of food security and sustainable agriculture. Issue Paper. Rome: Food and Agriculture Organization of the United Nations.
2. Gerbens-Leenes, P.W.; van Lienden, A.R.; Hoekstra, A.Y.; van der Meer, T.H. (2012) Biofuel scenarios in a water perspective: The global blue and green water footprint of road transport in 2030. Glob. Environ. Change-Human Policy Dimens. 22: 764-775
3. Gerbens-Leenes, P.W.; Xu, L.; de Vries, G.J.; Hoekstra, A.Y. (2014). The blue water footprint and land use of biofuels from algae. Water Resour. Res. 50: 8549-8563.
4. Avron, M., Ben Amotz, A. (1980) US Patent no. 4199895 Production of glycerol, carotenes and algae meal.
5. Harvey, P.J., Psycha, M., Kokossis, A., Abubakar A.L., Trivedi, V., Swamy, R., Cowan, A.K., Schroeder, D., Highfield, A., Reinhardt, G., Gartner, S., McNeil, J., Day, P., Brocken, M., Varrie, J., Ben-Amotz, A. (2012) Glycerol production by halophytic microalgae: strategy for producing industrial quantities in saline water. 20th EU Biomass Conf.&Exhib., 18-22 June 2012, Milan Italy pp 85-90.
6. Harvey et al (2014) The CO2 Microalgae Biorefinery: High Value Products from Low Value Wastes Using Halophylic Microalgae in the D-Factory. Part 1: Tackling Cell Harvesting DOI: 10.5071/22ndEUBCE2014-1CV.4.69  Proc. 22nd EU BC&E Pp 360 – 363
7. Psycha M., Pyrgakisa K., Harvey PJ et al (2014) Design Analysis of Integrated Microalgae Biorefineries. Computer Aided Chemical Engineering 34, 591–596