Innovative Gas Separations for Carbon Capture

Completed

Fossil Fuels: Oil Gas and Coal(CO2 Capture and Storage, CO2 capture/separation)

Basic and strategic applied research

PHYSICAL SCIENCES AND MATHEMATICS (Chemistry)
ENGINEERING AND TECHNOLOGY (Chemical Engineering)

Not Cross-cutting

Professor S Brandani
Materials and Processes
University of Edinburgh

Standard

EPSRC

01 October 2009

30 September 2013

48 months

£1,895,910

Energy

Scotland

Energy : Energy

Professor S Brandani, Materials and Processes, University of Edinburgh

Dr C Adjiman, Chemical Engineering, Imperial College London
Dr PM Budd, Chemistry, University of Manchester
Dr T Duren, Materials and Processes, University of Edinburgh
Dr P Fennell, Chemical Engineering, Imperial College London
Professor ES Fraga, Chemical Engineering, University College London
Dr A Galindo, Chemical Engineering, Imperial College London
Professor ZX Guo, Chemistry, University College London
Professor G Jackson, Chemical Engineering, Imperial College London
Professor GH Kelsall, Chemical Engineering, Imperial College London
Professor N McKeown, Chemistry, Cardiff University
Professor RE Morris, Chemistry, University of St Andrews
Dr L Sarkisov, Sch of Engineering and Electronics, University of Edinburgh
Dr FR Siperstein, Chemical Engineering and Analytical Science, University of Manchester
Dr PA Wright, Chemistry, University of St Andrews

The multi-disciplinary research teams collaborating in this proposal are all internationally leading groups which are at the forefront of research in the development of materials and processes for gas separations. The consortium will build upon its strengths in order to develop methodologies for the rapid synthesis and screening of novel materials and solvents for carbon capture from power stations. The research will focus on absorption, adsorption and membrane processes combining molecular modelling and advanced process modelling in order to develop reliable predictions of process performance.By 2030 up to 35 GW of new electricity generation capacity will be needed in the UK alone. Carbon Capture and Storage (CCS) will play a critical role in the production of a significant proportion of this electricity, enabling reduced greenhouse gas emissions and improving security of supply by maintaining a balanced mix of energy sources. Given the EU target of routine CCS deployment after 2020, and the fact that the UK has recently increased its target from 60% to 80% decarbonisation by 2050, it is now timely to establish high quality research consortia in this field. As pointed out in the Stern report, even in the best of possible scenarios more than 50% of the world energy will be from fossil fuels in 2050 and "CCS could help reduce emissions from the flood of new coal-fired power stations planned over the next decades, especially in India and China". CCS at this scale can be economically viable only if current costs in carbon capture are reduced significantly through a concerted research and development programme, a goal toward which this proposal aims to contribute

24/06/09