Sustainable bioenergy from microalgae: A systems perspective
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Global energy demand and the environmental consequences of fossil fuel combustion to satisfy this demand is proving to be unsustainable. Bio-energy has the potential to mitigate carbon emission concerns and provide a renewable option for energy generation. But, this requires development of sustainable processes that are economically viable. The concept of using photoautotrophic metabolism in microalgae to convert solar energy and carbon dioxide to organic fuel precursors is attractive for sustainable energy generation. However, development of efficient processes that use the concept to make a difference to the energy economy has so far proved elusive. We believe that a greater understanding of microalgae metabolism derived through a systems approach will make a difference to this scenario and enable development of sustainable processes for bio-energy generation, including approaches that use synthetic biology and metabolic engineering. The successful development of any such process will require characterisation of organisms that are relevant to field cultivation rather than just laboratory strains.
We aim to combine UK and Indian facilities and expertise in phycology, bioremediation, 'omic' characterisations and biochemical engineering to conduct a systems level investigation on selected microalgae isolates with potential to accumulate biofuel precursors and develop sustainable processes for bio-energy generation from microalgae in India and the UK. We will perform a systems level investigation in selected isolates to determine key metabolic steps involved in the synthesis of biofuel precursors (in particular, carbohydrates, triacylglycerols (TAGs) and hydrocarbons) in microalgae. This will lead to optimisation of conditions to maximize product yields, and the identification of gene targets for strain manipulations. We will also examine engineering approaches to enhance product recovery and investigate exemplar biorefinery cases to enable the development of sustainable processes for bio-energy generation.
Indian partners at BDU have established a repository of marine microalgae with DBT support that has over 500 isolates in its collection, from the rich biodiversity hotspots of tropical southern Indian coastal areas and psychrophilic strains from the Arctic. Some of these isolates have been assessed for biodiesel generation and will be available for the project. Freshwater microalgae characterised for hydrocarbon and TAG accumulation with prior DBT support is available at Madurai. In the UK, SAMS have extensive experience at characterisation and maintenance of microalgae with relevance to the development of UK-related processes. We will combine this expertise with algae systems biology expertise available at Sheffield and Cambridge to investigate how pathways involved in accumulation of storage compounds that are biofuel precursors and how establish its relationship with growth of the organism (Figure 1). A novel patented microbubble technology incorporated in an airlift loop bioreactor developed at Sheffield (WBJZ) will also be investigated for process improvements and product recovery.
The proposed work will result in the identification of key metabolic steps in relevant algal biotransformations, optimised conditions that maximise product yields and selected or novel strains for use in developing bioprocess for sustainable generation of fuel precursors that make a difference to the energy economy in India and the UK. We also propose to hold joint workshops in the two countries and exchange visits to enable transfer of knowledge and expertise between partners, with active industrial involvement.
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Technical Abstract:
Current methods to meet the growing energy demand are unsustainable and environmentally damaging. Bio-energy has the potential to mitigate carbon emission concerns and provide a renewable option for energy generation. But, this requires development of sustainable processes that are economically viable. The concept of using photoautotrophic metabolism in microalgae to convert solar energy and carbon dioxide to organic fuel precursors is attractive for sustainable energy generation. However, development of efficient processes that use the concept to make a difference to the energy economy has so far proved elusive. We believe that a greater understanding of microalgae metabolism derived through a systems approach will make a difference to this scenario and enable development of sustainable processes for bio-energy generation, including approaches that use synthetic biology and metabolic engineering. The successful development of any such process will require characterisation of organisms that are relevant to field cultivation rather than just laboratory strains. We aim to combine UK and Indian facilities and expertise in phycology, bioremediation, 'omic' characterisations and biochemical engineering to conduct a systems level investigation on selected microalgae isolates with potential to accumulate biofuel precursors and develop sustainable processes for bio-energy generation from microalgae in India and the UK. The proposed work will result in the identification of key metabolic steps in relevant algal biotransformations, optimised conditions that maximise product yields and selected or novel strains for use in developing bioprocess for sustainable generation of fuel precursors that make a difference to the energy economy in India and the UK. We also propose to hold joint workshops in the two countries and exchange visits to enable transfer of knowledge and expertise between partners, with active industrial involvement.
Potential Impact:
The two collaborating industrial partners (Pioneer Jellice Ltd in India and Celtic distilleries in Scotland) as their waste streams will be tested for improved microalgal bioenergy generation potential - leading to processes that they could adopt.
The proposed work will impact the algal research community, as the research conducted here will provide initial leads and background information for future developments of technology for bioenergy generation from microalgae
Both UK and India will stand to benefit from the proposed work as sustainable processes relevant to the geographical areas could be developed based on the results of the work proposed.
The work proposed will enhance our knowledgebase that will not only be applicable in India and the UK, but also globally, elsewhere.
There will be exchange of knowledge and awareness of the socio-economic needs for the development of sustainable processes in India and the UK, by investigators from both the countries.
The developed processes will contribute to environmental sustainability and attract public and private sector investments for R&D
there will be transnational skills training possible
| University of Sheffield | LEAD_ORG |
| Bharathidasan University | COLLAB_ORG |
| Varicon Aqua Solutions Ltd | COLLAB_ORG |
| C-Tech Innovation | COLLAB_ORG |
| Seetharaman Vaidyanathan | PI_PER |
| William Zimmerman | COI_PER |
| Alison Smith | COI_PER |
| Jagroop Pandhal | COI_PER |
| Michele Stanley | COI_PER |
| John Day | COI_PER |
| Phillip Craig Wright | COI_PER |
| Matthew Johnson | COI_PER |
| Daniel James Gilmour | COI_PER |
| Krystyna Kelly | RESEARCH_COI_PER |
Subjects by relevance
- Sustainable development
- Microalgae
- Biotechnology
- Algae
- Bioenergy
- Biofuels
- Biomass (industry)
- Carbon dioxide
- Sustainable use
- Energy production (process industry)
Extracted key phrases
- Sustainable energy generation
- Sustainable process relevant
- Sustainable generation
- Sustainable bioenergy
- Microalgal bioenergy generation potential
- Global energy demand
- Energy economy
- Solar energy
- Microalgae metabolism
- Algae system biology expertise available
- Marine microalgae
- Freshwater microalgae
- Efficient process
- Process improvement
- Organic fuel precursor