Major Theme |
Sub Theme |
Name |
Department |
Research |
---|---|---|---|---|
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Adjiman, Claire | Process Systems Engineering group (Chem Eng): 14 Dr. Claire Adjiman Dr. Benoit Chachuat Dr. Amparo Galindo Prof. George Jackson Dr. Cleo Kontoravdi Dr. Krishnan Prof. Sandro Macchietto Prof. Geoff Maitland Prof. Sakis Mantalaris Dr. Erich M | |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Armstrong, Alan | Chemistry | Development of new synthetic methodology and on target oriented organic synthesis |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Ashley, Andrew | Chemistry | Catalysis- Heterolytic hydrogen activation for the catalytic hydrogenation of small molecules |
Underpinning technologies | Synthetic Biology | Baldwin, Geoff | Life Sciences | Synthetic biology |
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Barahona, Mauricio | Mathematics | Mathematical modelling |
Application areas | Bioenergy/Biorenewables | Barber, Jim | Life Sciences | Photosynthesis |
Underpinning basic sciences and engineering | Chemical Biology | Barter, Laura | Chemistry | Director of Agri-net |
Application areas | Bioenergy/Biorenewables | Bauen, Ausilio | CEP | Techno-economic, environmental and policy aspects related to new and renewable energy technologies, with a focus on bioenergy systems |
Underpinning technologies | Synthetic Biology | Bayer, Travis | Life Sciences | Synthetic biology |
Application areas | Bioenergy/Biorenewables | Bayer, Travis | Life Sciences | Synthetic biology |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Bismarck, Alexander | Chemical Engineering | Advanced Materials |
Application areas | Bioenergy/Biorenewables | Brandon, Nigel (Energy Futures DTC) | ESE | Director of the Energy Futures Lab. Quantitative analysis of energy systems, with a particular focus on the design, characterisation, modelling, control and optimisation of fuel cells |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Britovsek, George | Chemistry | Ligand and metal complexes synthesis, bio-inspired catalyst design |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Britovsek, George | Chemistry | Ligand and metal complexes synthesis, bio-inspired catalyst design |
Underpinning basic sciences and engineering | Microbial physiology | Buck, Martin | Life Sciences | Study of bacterial systems, of agronomic, medical and industrial relevance |
Underpinning technologies | Underpinning technologies | Bundy, Jake (metabolomics) | Surgery and Cancer | Metabolomics |
Application areas | Bioremediation and Waste Treatment | Butler, Adrian | Civil Engineering | Subsurface Hydrology-remediation of organic pollutants for contaminated land. |
Application areas | Bioprocessing and Bioseparations | Byrne, Bernadette | Life Sciences | Molecular Membrane Biology |
Application areas | Biologics | Byrne, Bernadette | Life Sciences | Molecular Membrane Biology |
Underpinning basic sciences and engineering | Chemical Biology | Cass, Tony | Chemistry | Protein engineering, proteomics |
Application areas | Regenerative medicine and tissue engineering | Cass, Tony | Chemistry | Stem cell bioprocessing |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Chachuat, Benoit | Chemical Engineering | Integrated Microalgal-Bacterial Ecosystems for Bioenergy Production and processing/ waste water processing |
Application areas | Bioenergy/Biorenewables | Chachuat, Benoit | Chemical Engineering | Integrated Microalgal-Bacterial Ecosystems for Bioenergy Production and processing |
Application areas | Bioremediation and Waste Treatment | Chachuat, Benoit | Chemical Engineering | Waste water processing |
Application areas | Bioprocessing and Bioseparations | Chachuat, Benoit | Chemical Engineering | Integrated Microalgal-Bacterial Ecosystems for Bioenergy Production and processing/ waste water processing |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Crimmin, Mark | Chemistry | Developing new organometallic catalysts |
Underpinning technologies | Underpinning technologies | Dell, Anne (glycomics) | Life Sciences | Glycomics |
Underpinning basic sciences and engineering | Plant Sciences | Desikan, Radhika | Life Sciences | Signaling and adapation to stress |
Application areas | Bioenergy/Biorenewables | Diaz-Chavez, Rocio | CEP | Energy Policy |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Diez-Gonzalez, Silvia | Chemistry | Catalysis-development of novel well-defined organometallic complexes and their use in organic reactions |
Application areas | Bioprocessing and Bioseparations | Drakakis, Emmanual | Bioengineering | Biocircuits and systems |
Application areas | Regenerative medicine and tissue engineering | Dunlop, Iain | biomaterials-Nanotechnology and soft matter applied to cell biology | |
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Ebbels, Timothy | Surgery and Cancer | Computational bioinformatics, metabolomics |
Underpinning technologies | Underpinning technologies | Edel, Joshua | Chemistry | Nanotechnology |
Underpinning technologies | Synthetic Biology | Ellis, Tom | Life Sciences | Synthetic biology |
Underpinning technologies | Synthetic Biology | Freemont, Paul | Life Sciences | Synthetic biology |
Underpinning technologies | Underpinning technologies | French, Paul (imaging) | Physics | Imaging technology innnovation |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Galindo, Amparo | ||
Underpinning basic sciences and engineering | Catalysis/Synthesis | Hallett, Jason | Synthesis, Chemistry | Biomass conversions, biofuels synthesis |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Hallett, Jason | Synthesis, Chemistry | Biomass conversions, biofuels synthesis |
Application areas | Bioenergy/Biorenewables | Hallett, Jason | Chemistry | Biomass conversions, biofuels synthesis |
Underpinning basic sciences and engineering | Plant Sciences | Hamann, Thorsten | Life Sciences | Plant cell wall related processes in particular cell wall signalling and remodelling |
Application areas | Bioenergy/Biorenewables | Hamann, Thorsten | Life Sciences | Plant cell wall related processes in particular cell wall signalling and remodelling |
Application areas | Bioenergy/Biorenewables | Hamann, Thorsten | Life Sciences | |
Underpinning basic sciences and engineering | Flow Chemistry | Hellgardt, Klaus | Chemical Engineering | |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Hellgardt, Klaus | Chemical Engineering | reaction engineering, chemistry and materials science including the areas of catalysis, membrane science and smart materials applications |
Underpinning basic sciences and engineering | Flow Chemistry | Hii, Mimi | Chemistry | Transition metal mediated organic synthesis and asymmetric catalysis |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Hunt, Tricia | Chemistry | Computational methods applied to inorganic systems and molecular liquids |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Hunt, Tricia | Chemistry | Computational methods applied to inorganic systems and molecular liquids |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Jackson, george | ||
Application areas | Regenerative medicine and tissue engineering | Jones, Julian | Materials | Biomaterials for regenerative medicine- scaffolds suitable for tissue engineering |
Underpinning technologies | Underpinning technologies | Kazarian, Sergei (spectroscopy) | Chemical Engineering | Spectroscopy |
Underpinning technologies | Synthetic Biology | Kitney, Dick | Bioengineering | Synthetic biology |
Underpinning technologies | Underpinning technologies | Klug, David (novel proteomic tools) | Chemistry | Novel proteomic tools |
Underpinning basic sciences and engineering | Flow Chemistry | Kogelbauer, Andreas | Chemical Engineering | |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Kontoravdi, Cleo | ||
Underpinning technologies | Synthetic Biology | Kontoravdi, Cleo | Chemical Engineering | Synthetic biology |
Application areas | Bioprocessing and Bioseparations | Kontoravdi, Cleo | ||
Application areas | Biologics | Kontoravdi, Cleo | Chemical Engineering | Biotechnology and Bioprocess Engineering Group |
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Krishnan, J | Chem Eng | Mathematical modelling |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Krishnan, J | ||
Underpinning basic sciences and engineering | Chemical Biology | Leatherbarrow, Robin | Chemistry | Enzymology |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Li, Kang | Chemical Engineering (Chemical Engineering: Biotechnology and Bioprocess Engineering Research group, Centre for Process Systems Engineering and Biological Systems Engineering Lab | Biotechnology and Bioprocess Engineering Group- Chem Eng (6 PI) |
Application areas | Bioremediation and Waste Treatment | Li, Kang | Chemical Engineering | Development of various hollow fibre membranes and membrane systems for fluid separations/reactions- Membranes for Waste Treatment |
Application areas | Bioprocessing and Bioseparations | Li, Kang | Chemical Engineering, iotechnology and Bioprocess Engineering Research group | Biotechnology and Bioprocess Engineering Group- Chem Eng (6 PI) |
Application areas | Bioenergy/Biorenewables | Links with UKERC | ||
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Livingston, Andrew | ||
Application areas | Bioprocessing and Bioseparations | Livingston, Andrew | ||
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Macchietto, Sandro | ||
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Maitland, Geoff | ||
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Mantalaris, Sakis | ||
Application areas | Bioremediation and Waste Treatment | Mantalaris, Sakis | Chemical Engineering | Targeting environmental pollution with engineered microbial systems a la carte |
Application areas | Bioprocessing and Bioseparations | Mantalaris, Sakis | ||
Application areas | Biologics | Mantalaris, Sakis | Chemical Engineering | Stem cell bioprocessing |
Application areas | Regenerative medicine and tissue engineering | Mantalaris, Sakis | Chemical Engineering | Stem cell bioprocessing |
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Muggleton, Stephen | Computing | Systems biology/computing |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Muller, Erich | ||
Underpinning technologies | Synthetic Biology | Murray, James | Life Sciences | Synthetic biology |
Application areas | Bioenergy/Biorenewables | Murray, James | Life Sciences | Biomass from cyanobacteria and algae (Chlamydymonas)- working with Chemical Engineering |
Application areas | Non-food crop/Non Food Application | N/A | N/A | Use of crops for purposes other than food |
Underpinning technologies | Underpinning technologies | Nicholson, Jeremy (metabolomics) | Surgery and Cancer | Metabolomics |
Application areas | Bioenergy/Biorenewables | Nixon, Peter | Life Sciences | |
Underpinning technologies | Synthetic Biology | Other members of IoSSB/CSynBI: Buck, Sternberg, Stumpf, Endres, Barahona, Boutelle, Dickinson, Faisal, Mantalaris, Bismarck, Murray, Muggleton, Ces, Templer, Stevens, Jones | Numerous | Synthetic biology |
Application areas | Bioenergy/Biorenewables | Panoutsou, Calliope | CEP | Energy Policy |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Pantelides, Costas | ||
Application areas | Bioenergy/Biorenewables | PI of BSBEC grants | ||
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Pinney, John | Life Sciences | Theoretical systems biology |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Pistikopoulos, Stratos | ||
Application areas | Bioprocessing and Bioseparations | Pistikopoulos, Stratos | ||
Underpinning technologies | Synthetic Biology | Polizzi, Karen | Life Sciences | Synthetic biology |
Application areas | Bioprocessing and Bioseparations | Polizzi, Karen | Life Sciences | Biopharmaceutical Processing- in vivo biosensors and synthetic biology. |
Application areas | Biologics | Polizzi, Karen | Life Sciences | Biopharmaceutical Processing- in vivo biosensors and synthetic biology. |
Application areas | Bioenergy/Biorenewables | Porter Alliance | ||
Application areas | Regenerative medicine and tissue engineering | Porter, Alexandra | Electron microscopy of biomaterials' interfaces | |
Application areas | Regenerative medicine and tissue engineering | Riley, Jason | Preparation, characterisation and applications of nanomaterials in electrochemistry | |
Application areas | Bioenergy/Biorenewables | Rutherford, Alfred | Life Sciences | |
Application areas | Regenerative medicine and tissue engineering | Ryan, Mary | Applied electrochemistry and corrosion | |
Underpinning basic sciences and engineering | Plant Sciences | Sena, Giovanni | Life Sciences | Imaging and modeling plant root development) |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Shah, Nilay | ||
Application areas | Bioenergy/Biorenewables | Slade, Raphael | CEP | Energy Policy |
Application areas | Bioremediation and Waste Treatment | Smith, Stephen | Civil Engineering | Bioresource Systems |
Underpinning basic sciences and engineering | Plant Sciences | Spanu, Pietro | Life Sciences | Molecular plant pathology |
Application areas | Regenerative medicine and tissue engineering | Staff within Dept. of Surgery and Cancer | Dept. of Surgery and Cancer | |
Underpinning technologies | Synthetic Biology | Stan, Guy-Bart | Bioengineering | Synthetic biology |
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Sternberg, Mike | Life Sciences/ | Bioinformatics and Systems biology |
Application areas | Regenerative medicine and tissue engineering | Stevens, Molly | Materials/Bioengineering | Biomedical Materials and Regenerative Medicine |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Stuckey, David | ||
Underpinning technologies | Biocatalysis and metabolic engineering | Stuckey, David | Chemical Engineering | Biocatalysis: isolated enzymes or whole cells to carry out chemical reactions. Production of useful enzymes from new sources (plants microorganisms etc). |
Application areas | Bioremediation and Waste Treatment | Stuckey, David | Chemical Engineering | Anaerobic waste water treatment |
Application areas | Bioprocessing and Bioseparations | Stuckey, David | ||
Underpinning basic sciences and engineering | Systems biology and mathematical modelling | Stumpf, Michael | Life Sciences | Theoretical systems biology |
Underpinning basic sciences and engineering | Chemical Biology | Tate, Ed | Chemistry | Protein Chemistry |
Underpinning basic sciences and engineering | Chemical Biology | Templer, Richard | Chemistry | Director of Climate KIC. Chemical biology/lipid membranes |
Application areas | Bioenergy/Biorenewables | Templer, Richard | Chemistry | Director of Climate KIC. Chemical biology/lipid membranes |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Thornhill, Nina | ||
Application areas | Regenerative medicine and tissue engineering | Tissue Engineering and Regenerative Medicine Centre | Faculty of Medicine | |
Underpinning basic sciences and engineering | Plant Sciences | Turnbull, Colin | Life Sciences | Molecular plant physiology/ feedstock production |
Application areas | Regenerative medicine and tissue engineering | Weaver, Jon | Synthetic polymer chemistry and functional biomaterials | |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Welton, Tom | Chemistry | Synthesis and catalysis in novelionic |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Welton, Tom | Chemistry | Synthesis and catalysis in novelionic |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Williams, Charlotte | Chemistry | Catalysts for the synthesis of biodegradable and biocompatible polymers |
Underpinning basic sciences and engineering | Catalysis/Synthesis | Wilton-Ely, James | Chemistry | Functionalised nanoparticles for catalysis and sensing |
Underpinning basic sciences and engineering | Sustainable manufacturing processes/construction: | Wilton-Ely, James | Chemistry | Functionalised nanoparticles for catalysis and sensing |
Application areas | Bioenergy/Biorenewables | Woods, Jem | CEP | Policy (ICEPT), bioenergy |
Underpinning basic sciences and engineering | Chemical Biology | Woscholski, Rudiger | Chemistry | Director of Agri-net |
Underpinning basic sciences and engineering | Process Design, including Bioreactors | Xu, Xiao | mechanics and transport processes in biological and physiological systems | |
Application areas | Regenerative medicine and tissue engineering | Xu, Xiao | Chemical Engineering | Biomechanics with tissue engineering |