Log in
The Abraham solvation parameter approach developed at UCL has become integral to the work carried out by drug discovery teams at [text removed for publication] and other major pharmaceutical companies, as well as research and development groups at international chemical companies including Syngenta and [text removed for publication]. It enables chemists to predict physicochemical and biochemical properties of chemicals, including drugs and agrochemicals, rapidly and efficiently, without the need to conduct time-consuming experiments. The method helps drug discovery teams to identify and optimise the most promising compounds, and often results in fewer compounds being made before a candidate is selected, saving time and resources. The approach has been integrated into software used for drug discovery [text removed for publication].
In partnership with the US company Nalco, the University's Surfactant & Colloid Group developed a new multifunctional technology (Clean n Cor) for the oil industry that both removes accumulated deposits at a metal surface (enabling "break-through" of corrosion inhibitor to the metal surface) and inhibits corrosion. Clean n Cor technology not only protects assets such as oil pipelines against corrosion but also maximises oil production through enhancing water injectivity (water flow per unit pressure drop). Since its launch in 2007, it is currently one of Nalco's fastest growing new technologies and is used at over 100 production locations worldwide.
Novel vapour sorption experimental methods for the characterisation of complex particulate materials have been developed in the Department of Chemical Engineering. This research and expertise resulted in the creation of Surface Measurement Systems Limited (SMS), whose Dynamic Vapour Sorption (DVS) and Inverse Gas Chromatography (IGC) instruments are now found in >500 laboratories around the world. They are recognised standard research and development tools in the global pharmaceutical industry (DIN 66138). SMS has contributed >270 man-years of employment and generated £27M of turnover, whilst SMS instruments have generated over £300M of economic value, over the REF period.
The SAFT-VR family of thermodynamic models has made it possible to predict reliably the behaviour of the many complex and challenging fluids that are found across a range of industrial sectors, including oil & gas, chemicals (refrigerants, surfactants, polymers), energy (carbon capture solvents, carbon dioxide-rich streams) and pharmaceuticals.
The SAFT-VR models have had a wide impact on industrial practice. At BP, they have been used to design novel surfactants that have increased the lifetime of oil fields up to five-fold, avoiding maintenance interventions costing millions of dollars and increasing productivity by 50% (worth $2-3 million per year per well). At Borealis, they have been used to understand how to increase the productivity of the reactor in the flagship Borstar process by 30%. At ICI and Ineos/Mexichem, they have been used to design efficient processes for producing replacement refrigerants with much reduced reliance on extreme and expensive experiments involving hydrogen fluoride, a highly corrosive substance. Industrial demand for access to the predictive capabilities of SAFT-VR has been such that Imperial College has licensed the software in 2013 to a UK SME in order to distribute it worldwide to users.
Research into electrochemical biosensors conducted at the University of Cambridge between 1998 and 2002 led to the development of the WaveSense™ line of diabetes products by start-up, AgaMatrix. By 2012 AgaMatrix had sold 3M glucose meters & 3B biosensor test strips worldwide across 20,000+ retail locations including Boots UK, and since 2010 also globally in partnership with Sanofi. [text removed for publication] AgaMatrix UK continues to grow its business with compound annual growth rates for revenue in excess of 100%. Agamatrix UK now supplies over one million glucose test strips per month to the NHS. Agamatrix has developed >10 FDA-cleared products since 2008, including the first FDA approved smartphone linked diagnostic device.
Mineral separation by froth flotation is the largest tonnage separation process in the world, and is used to recover the very small fraction (<0.5%) of valuable mineral from the mined ore. Typically, 5-15% of the valuable minerals are not recovered due to sub-optimal process settings, most important of which is the air rate. A methodology to determine the optimal air rate range to use, Peak Air Recovery (PAR), was developed by the Froth and Foam Research Group at Imperial College London.
Anglo American Platinum produces 40% of the world's platinum. They use the PAR methodology on all their flotation plants to establish to air rate control limits, tightening the operating range and improving the separation performance. Rio Tinto annually produce 300 000 tons of copper and 500 000 oz gold from their Kennecott Copper mine. They have implemented PAR as a control strategy, and statistical comparative tests have shown an increase in copper and gold recovery from this mine alone of the order of 1%, with a nominal value of approximately $30m per annum.
Our research on semiconductor materials and devices has led to the establishment by e2v Technologies of a combined manufacturing, research and development facility within the School of Physics and Astronomy. We have adapted and transferred device simulation software to e2v, and have provided epitaxially-grown semiconductors and access to fabrication facilities which have been used in their manufacturing processes. Devices fabricated within the facility, which was opened in 2011, have generated sales of £7M for e2v. This initiative has also led to shifts in the investment priorities of e2v, and mitigated risks to the company arising from import restrictions associated with the US International Traffic in Arms Regulations (ITAR).
Research on ester liquids (ELs) has proved they can be used in high-voltage (HV) transformers, bringing economic and safety advantages to the power industry and environmental benefits to society. Impact includes revisions to National Grid's oil policy recommending ester-filled HV transformers for use in London and the design and operation of the first 132kV "green" transformer (valued between £1m and £2m). The research has led directly to the creation of two international standards for professionals in global power utilities specifying the use of ELs in transformers. These developments have contributed directly to Manchester SME M&I Materials increasing sales from £15m (2008) to £29m (2012).
A range of techniques based on laser physics and developed since 1993 by the group of Prof Telle in our analytical laser spectroscopy unit (ALSU) has led to:
This case study concerns the long term (energy) sustainability of emerging winemaking regions. Underpinning research in energy efficiency and renewable technologies informs the case study in determining energy usage and benchmarks, development of energy guidelines/policy, implementation by national professional bodies and adoption of energy best practice by the local industry. Impact is through the adoption and application of benchmarks by winemaking associations, directly influencing (through policy, regulations and standards) the energy expended in making wine. The study is underpinned by international publishing accolades (Solar Energy `Best Full Length Paper in Photovoltaics', Mondol et al, 2005) and a highly prestigious personal Royal Academy of Engineering Global Research Award to Smyth.