Interspecies electron transfer in biotechnology. While the project is fundamental in nature, it has direct technological gains to a wide range of biotechnology processes, and in particular, mixed culture anaerobic biotechnology. It therefore promotes Australian bioenergy, biofuel, and commodity renewable chemicals industries, and contributes to the national research priority of an Environmentally Sustainable Australia. In addition, this is a fast moving, high impact area that will demonstrate e ....Interspecies electron transfer in biotechnology. While the project is fundamental in nature, it has direct technological gains to a wide range of biotechnology processes, and in particular, mixed culture anaerobic biotechnology. It therefore promotes Australian bioenergy, biofuel, and commodity renewable chemicals industries, and contributes to the national research priority of an Environmentally Sustainable Australia. In addition, this is a fast moving, high impact area that will demonstrate excellence in Australian research on an international scale. The exciting multidisciplinary nature of the project, excellent management team, and high-class partners will also provide for an excellent experience for the three PhD candidates to be educated through the project.Read moreRead less
Surface immobilisation of enzymes for the synthesis of ethanol. The efficiency of ethanol production will be increased by preventing poisoning of enzymes by reaction products as in current technology. Enzymes will be robustly attached to porous surfaces so that a high efficiency continuous flow process can be used. A novel selective membrane for the continuous removal of ethanol will be developed, allowing water to be saved and unreacted inputs to be recycled. The ultimate outcome will be a proc ....Surface immobilisation of enzymes for the synthesis of ethanol. The efficiency of ethanol production will be increased by preventing poisoning of enzymes by reaction products as in current technology. Enzymes will be robustly attached to porous surfaces so that a high efficiency continuous flow process can be used. A novel selective membrane for the continuous removal of ethanol will be developed, allowing water to be saved and unreacted inputs to be recycled. The ultimate outcome will be a process which achieves dramatic water saving and greatly reduced environmental impact. In the final stage of the project we will apply our methods to the processing of cellulose from agricultural and forestry waste, with the potential of preventing the diversion of food resources into the transport fuel industry.Read moreRead less