Global Energy demand is expected to increase by up to 40% by 2030. The key challenge facing the global community is to not only increase the sources of energy supply, but to also maximize the use of sustainable forms of energy to safeguard the environment while ensuring that the latter do not detrimentally impact food supplies. In this regard, renewable sources of energy will play an increasing role in the global primary energy supply. The UK government, along with the majority of the civilised world, have now set challenging targets for reductions in greenhouse gas (GHG). Centre stage is the need for the sustainable production of hydrocarbons for energy, lubricants, and high value chemicals. Traditional routes to chemical generation through biological systems have been reliant on the conversion of the more tractable components of plant biomass (sugars and starch) into chemicals, and in particular biofuels. The microbes employed ferment the easily accessible sugar and/or starch of plants, such as sugar cane or corn, and convert them into biofuels, most commonly ethanol. This has led to concerns over competition with use of these products as food, and a re-focussing of efforts on so-called 'second generation' biofuels. These are generated from cell wall material (lignocellulose) derived from non-food crops or agricultural wastes, such as willow and straw, respectively. Cell wall material is a product of photosynthesis, whereby plants convert atmospheric carbon dioxide gas (CO2) into sugars which are then used to assemble the complex carbon-based polymer, lignocellulose. For the fermentative growth of microbes on plant cell walls, lignocellulose must first be converted back into simple sugars. However, lignocellulose is extremely resistant to breakdown. Overcoming this recalcitrance in a cost effective manner is proving extremely challenging. An alternative route would be to directly capture carbon, by harnessing the ability of certain bacteria, typified by Clostridium ljungdahli, to 'eat' the gas carbon monoxide (CO). When CO is injected into the liquid medium of fermentation vessels it is consumed by Clostridium ljungdahlii and converted into ethanol. Fortunately, CO is an abundant resource, and a waste product of industries such as steel manufacturing, oil refining and chemical production. Moreover, it can be readily generated in the form of Synthesis Gas ('Syngas'), by the gasification (heating) of forestry and agricultural residues, municipal waste and coal. By allowing the use of all these available low cost, non-food resources, such a process both overcomes the "Food versus Fuel" issues associated with traditional ethanol production, and circumvents many of the challenges associated with 'second generation' biofuels. Furthermore, capturing the large volume of CO (destined to become CO2 once released into the atmosphere) emitted by industry for fuel and chemical production provides a net reduction in fossil carbon emissions. The Industrial Partner in this project, LanzaTech, have developed a versatile and robust process based on such a 'gas-eating' bacterium, and demonstrated its ability to produce chemicals from the off-gas of a Steel plant. Current products include ethanol, and another alcohol (butanediol) which, unlike ethanol, has potential as a valuable chemical, solvent or polymer. The University of Nottingham has developed world-leading genetic tools which can be used to both enhance the productivity of the current process, and extend the number of products the organism can make. Working together, the Nottingham tools will be used to improve our understanding of how LanzaTech's 'gas-eating' bugs convert carbon monoxide into chemicals. Thereafter, this knowledge will be exploited to both increase the yields of existing products, and extend the range of useful chemicals that can be made.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Sustainability is defined as "the ability to meet the needs of the present without compromising the ability of future generations to meet their own needs". Achieving sustainable development is the key global challenge of the 21st Century. It can only be met with the adoption of a range of new sustainable technologies. Sustainable chemical technologies are those involving chemistry as the central science. They span a wide range of areas, many of which make major impacts on society. Key sustainable chemical technologies include: use of renewable resources and biotechnology (e.g., making fuels, chemicals and products from biomass rather than petrochemicals); clean energy conversion and storage (e.g., solar energy, the hydrogen economy and advanced battery technologies); sustainable use of water (e.g., membrane technologies for water purification and upcycling of nutrients in waste water); developing sustainable processes and manufacturing (e.g., making production of chemicals, pharmaceuticals and plastics more energy-efficient and less wasteful through developing sustainable supply chains as well as through technological advances); and developing advanced healthcare technologies (e.g., developing new drugs, medical treatments and devices). To address these needs, we propose a Centre for Doctoral Training (CDT) in Sustainable Chemical Technologies. The £5.08m requested from the EPSRC will be supplemented by £2.0m from the University and a £4.13m industrial contribution. The CDT will place fundamental concepts of sustainability at the core of a broad spectrum of research and training at the interfaces of chemistry, chemical engineering, biotechnology and manufacturing. This will respond to a national and global need for highly skilled and talented scientists and engineers in the area as well as training tomorrow's leaders as advocates for sustainable innovation. All students will receive foundation training to supplement their undergraduate knowledge, in addition to training in Sustainable Chemical Technologies. Broader training and practice in public engagement and creativity will encourage responsible innovation and attention to ethical, societal, and business aspects of research. They will all conduct high quality and challenging research directed by supervisory teams comprising joint supervisors from at least two of the disciplines of chemistry, chemical engineering, biotechnology and management as well as an industrial and/or international advisor. The broad research themes encompass the areas of: Renewable Resources and Biotechnology, Energy and Water, Processes and Manufacturing and Healthcare Technologies. Participation from key industry partners will address stakeholder needs, and partner institutions in the USA, Germany, Australia, and South Korea will provide world-leading international input, along with exciting opportunities for student placements and internships. The CDT will utilize dedicated physical and virtual space for the students as well as a supervisory base of more than fifty academics. Building on the success of the current Doctoral Training Centre and evolving to keep pace with the growing importance of biotechnology and manufacturing to UK industry, the centre will provide a dynamic and truly multidisciplinary environment for innovative PhD research and training.