SynHiSel

Started

Not Energy Related
Energy Efficiency(Industry)

Basic and strategic applied research

ENGINEERING AND TECHNOLOGY (Chemical Engineering)
ENGINEERING AND TECHNOLOGY (Mechanical, Aeronautical and Manufacturing Engineering)

Not Cross-cutting

Dr D Mattia
Chemical Engineering
University of Bath

Standard

EPSRC

01 February 2022

31 July 2027

66 months

£7,328,275

Process engineering

South West

NC : Engineering

Dr D Mattia, Chemical Engineering, University of Bath

Dr PM Budd, Chemistry, University of Manchester
Dr YMJ Chew, Chemical Engineering, University of Bath
Dr M Ferrari, Sch of Engineering and Electronics, University of Edinburgh
Dr K Li, Chemical Engineering, Imperial College London
Professor A Livingston, Engineering and Materials Science, Queen Mary University of London
Professor N McKeown, Chemistry, Cardiff University
Professor IS Metcalfe, School of Chemical Engineering & Advanced Materials, Newcastle University
Dr GA Mutch, Sch of Engineering, Newcastle University
Miss M Perez-Page, Chemical Engineering and Analytical Science, University of Manchester
Dr Q Song, Chemical Engineering, Imperial College London

Project Contact, RFC Power
Project Contact, Pall Europe Ltd
Project Contact, DuPont Teijin Films UK Limited
Project Contact, ExxonMobil International Ltd
Project Contact, Exactmer Limited
Project Contact, Graphene Water Technologies
Project Contact, Cytiva Europe
Project Contact, Nanotherics Ltd
Project Contact, BP PLC
Project Contact, Evonik Industries AG, Germany
Project Contact, Laser Micromachining Limited
Project Contact, Naturbeads

Chemical separations are critical to almost every aspect of our daily lives, from the energy we use to the medications we take, but consume 10-15% of the total energy used in the world. It has been estimated that highly selective membranes could make these separations 10-times more energy efficient and save 100 million tonnes/year of carbon dioxide emissions and £3.5 billion in energy costs annually (US DoE). More selective separation processes are essential to "maximise the advantages for UK industry from the global shift to clean growth", and will assist the move towards "low carbon technologies and the efficient use of resources" (HM Govt Clean Growth Strategy, 2017). In the healthcare sector there is growing concern over the cost of the latest pharmaceuticals, which are often biologicals, with an unmet need for highly selective separation of product-related impurities such as active from inactive viruses (HM Govt Industrial Strategy 2017). In the water sector, the challenges lie in the removal of ions and small molecules at very low concentrations, so-called micropollutants (Cave Review, 2008). Those developing sustainable approaches to chemicals manufacture require novel separation approaches to remove small amounts of potent inhibitors during feedstock preparation. Manufacturers of high-value products would benefit from higher recovery offered by more selective membranes.In all these instances, higher selectivity separation processes will provide a step-change in productivity, a critical need for the UK economy, as highlighted in the UK Government's Industrial Strategy and by our industrial partners.SynHiSel's vision is to create the high selectivity membranes needed to enable the adoption of a novel generation of emerging high-value/high-efficiency processes.Our ambition is to change the way the global community perceives performance, with a primary focus on improved selectivity and its process benefits - while maintaining gains already made in permeance and longevity.

13/04/22