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- All Subjects: Biofuel
- Creators: Landis, Amy E.
- Creators: Bahrami Dizicheh, Zahra
Description
Overall, biofuels play a significant role in future energy sourcing and deserve thorough researching and examining for their best use in achieving sustainable goals. National and state policies are supporting biofuel production as a sustainable option without a holistic view of total impacts. The analysis from this research connects to policies based on life cycle sustainability to identify other environmental impacts beyond those specified in the policy as well as ethical issues that are a concern. A Life cycle assessment (LCA) of switchgrass agriculture indicates it will be challenging to meet U.S. Renewable Fuel Standards with only switchgrass cellulosic ethanol, yet may be used for California's Low Carbon Fuel Standard. Ethical dilemmas in food supply, land conservation, and water use can be connected to biofuel production and will require evaluation as policies are created. The discussions around these ethical dilemmas should be had throughout the process of biofuel production and policy making. Earth system engineering management principles can help start the discussions and allow anthropocentric and biocentric viewpoints to be heard.
ContributorsHarden, Cheyenne (Author) / Landis, Amy E. (Thesis advisor) / Allenby, Braden (Committee member) / Khanna, Vikas (Committee member) / Arizona State University (Publisher)
Created2014
Description
To date, the production of algal biofuels is not economically sustainable due to the cost of production and the low cost of conventional fuels. As a result, interest has been shifting to high value products in the algae community to make up for the low economic potential of algal biofuels. The economic potential of high-value products does not however, eliminate the need to consider the environmental impacts. The majority of the environmental impacts associated with algal biofuels overlap with algal bioproducts in general (high-energy dewatering) due to the similarities in their production pathways. Selecting appropriate product sets is a critical step in the commercialization of algal biorefineries.
This thesis evaluates the potential of algae multiproduct biorefineries for the production of fuel and high-value products to be economically self-sufficient and still contribute to climate change mandates laid out by the government via the Energy Independence and Security Act (EISA) of 2007. This research demonstrates:
1) The environmental impacts of algal omega-3 fatty acid production can be lower than conventional omega-3 fatty acid production, depending on the dewatering strategy.
2) The production of high-value products can support biofuels with both products being sold at prices comparable to 2016 prices.
3) There is a tradeoff between revenue and fuel production
4) There is a tradeoff between the net energy ratio of the algal biorefinery and the economic viability due to the lower fuel production in a multi-product model that produces high-value products and diesel vs. the lower economic potential from a multi-product model that just produces diesel.
This work represents the first efforts to use life cycle assessment and techno-economic analysis to assess the economic and environmental sustainability of an existing pilot-scale biorefinery tasked with the production of high-value products and biofuels. This thesis also identifies improvements for multiproduct algal biorefineries that will achieve environmentally sustainable biofuel and products while maintaining economic viability.
This thesis evaluates the potential of algae multiproduct biorefineries for the production of fuel and high-value products to be economically self-sufficient and still contribute to climate change mandates laid out by the government via the Energy Independence and Security Act (EISA) of 2007. This research demonstrates:
1) The environmental impacts of algal omega-3 fatty acid production can be lower than conventional omega-3 fatty acid production, depending on the dewatering strategy.
2) The production of high-value products can support biofuels with both products being sold at prices comparable to 2016 prices.
3) There is a tradeoff between revenue and fuel production
4) There is a tradeoff between the net energy ratio of the algal biorefinery and the economic viability due to the lower fuel production in a multi-product model that produces high-value products and diesel vs. the lower economic potential from a multi-product model that just produces diesel.
This work represents the first efforts to use life cycle assessment and techno-economic analysis to assess the economic and environmental sustainability of an existing pilot-scale biorefinery tasked with the production of high-value products and biofuels. This thesis also identifies improvements for multiproduct algal biorefineries that will achieve environmentally sustainable biofuel and products while maintaining economic viability.
ContributorsBarr, William James (Author) / Landis, Amy E. (Thesis advisor) / Westerhoff, Paul (Thesis advisor) / Rittmann, Bruce (Committee member) / Khanna, Vikas (Committee member) / Arizona State University (Publisher)
Created2016
Description
Redox enzymes represent a big group of proteins and they serve as catalysts for
biological processes that involve electron transfer. These proteins contain a redox center
that determines their functional properties, and hence, altering this center or incorporating
non-biological redox cofactor to proteins has been used as a means to generate redox
proteins with desirable activities for biological and chemical applications. Porphyrins and
Fe-S clusters are among the most common cofactors that biology employs for electron
transfer processes and there have been many studies on potential activities that they offer
in redox reactions.
In this dissertation, redox activity of Fe-S clusters and catalytic activity of porphyrins
have been explored with regard to protein scaffolds. In the first part, modular property of
repeat proteins along with previously established protein design principles have been
used to incorporate multiple Fe-S clusters within the repeat protein scaffold. This study is
the first example of exploiting a single scaffold to assemble a determined number of
clusters. In exploring the catalytic activity of transmetallated porphyrins, a cobalt-porphyrin
binding protein known as cytochrome c was employed in a water oxidation
photoelectrochemical cell. This system can be further coupled to a hydrogen production
electrode to achieve a full water splitting tandem cell. Finally, a cobalt-porphyrin binding
protein known as cytochrome b562 was employed to design a whole cell catalysis system,
and the activity of the surface-displayed protein for hydrogen production was explored
photochemically. This system can further be expanded for directed evolution studies and
high-throughput screening.
biological processes that involve electron transfer. These proteins contain a redox center
that determines their functional properties, and hence, altering this center or incorporating
non-biological redox cofactor to proteins has been used as a means to generate redox
proteins with desirable activities for biological and chemical applications. Porphyrins and
Fe-S clusters are among the most common cofactors that biology employs for electron
transfer processes and there have been many studies on potential activities that they offer
in redox reactions.
In this dissertation, redox activity of Fe-S clusters and catalytic activity of porphyrins
have been explored with regard to protein scaffolds. In the first part, modular property of
repeat proteins along with previously established protein design principles have been
used to incorporate multiple Fe-S clusters within the repeat protein scaffold. This study is
the first example of exploiting a single scaffold to assemble a determined number of
clusters. In exploring the catalytic activity of transmetallated porphyrins, a cobalt-porphyrin
binding protein known as cytochrome c was employed in a water oxidation
photoelectrochemical cell. This system can be further coupled to a hydrogen production
electrode to achieve a full water splitting tandem cell. Finally, a cobalt-porphyrin binding
protein known as cytochrome b562 was employed to design a whole cell catalysis system,
and the activity of the surface-displayed protein for hydrogen production was explored
photochemically. This system can further be expanded for directed evolution studies and
high-throughput screening.
ContributorsBahrami Dizicheh, Zahra (Author) / Ghirlanda, Giovanna (Thesis advisor) / Allen, James P. (Committee member) / Seo, Dong Kyun (Committee member) / Arizona State University (Publisher)
Created2019