Bio-derived and Bio-inspired Advanced Materials for Sustainable Industries (VALUED)
Lead Research Organisation:
Imperial College London
Department Name: Chemical Engineering
Abstract
The UK Government recently set targets for "net zero emissions" and "zero waste" as well as a 10 Point Plan for a Green Industrial Revolution. Even so, the UK currently sources, processes and deploys advanced materials based on unsustainable practices, including the use of fossil fuels and scarce, geologically hindered raw materials. This contributes to over 30% of the UK CO2 emissions, especially considering the import of raw precursors and materials.
Our vision is to build our most important functional materials from bio-based resources which are locally available. These materials will lower CO2 emissions, helping the UK to reach the targeted zero emissions by 2050 while boosting high-performance, locally available technologies and creating new industries. They will form the cornerstone for a modern technology-dependent economy.
This programme grant brings together the best UK academics and key industrial partners involved in the development of a new supply chain for sustainable materials and applications. We will accelerate novel pathways to manufacture advanced materials out of available UK bioresources while boosting their performance working with stakeholders in key industrial sectors (chemical industry, advanced materials, energy, waste, agriculture, forestry, etc).
The combined food, forestry and agricultural waste in the UK amounts to approx.26.5m tonnes each year. There is no valuable economic chain in the UK to allow waste valorisation towards high value-added materials. Yet, by mass, functional materials provide the most viable route for waste utilisation, preferable over waste-to-energy. This Programme Grant will thus enhance the UK's capability in the critical area of affordable and sustainable advanced materials for a zero carbon UK economy, providing multidisciplinary training for the next generation of researchers, and support for a nascent next generation of an advanced materials industry
Our vision is to build our most important functional materials from bio-based resources which are locally available. These materials will lower CO2 emissions, helping the UK to reach the targeted zero emissions by 2050 while boosting high-performance, locally available technologies and creating new industries. They will form the cornerstone for a modern technology-dependent economy.
This programme grant brings together the best UK academics and key industrial partners involved in the development of a new supply chain for sustainable materials and applications. We will accelerate novel pathways to manufacture advanced materials out of available UK bioresources while boosting their performance working with stakeholders in key industrial sectors (chemical industry, advanced materials, energy, waste, agriculture, forestry, etc).
The combined food, forestry and agricultural waste in the UK amounts to approx.26.5m tonnes each year. There is no valuable economic chain in the UK to allow waste valorisation towards high value-added materials. Yet, by mass, functional materials provide the most viable route for waste utilisation, preferable over waste-to-energy. This Programme Grant will thus enhance the UK's capability in the critical area of affordable and sustainable advanced materials for a zero carbon UK economy, providing multidisciplinary training for the next generation of researchers, and support for a nascent next generation of an advanced materials industry
Organisations
- Imperial College London (Lead Research Organisation)
- Bio bean (United Kingdom) (Project Partner)
- University of Milan (Project Partner)
- BP (United Kingdom) (Project Partner)
- Lixea Limited (Project Partner)
- Freeland Horticulture (Project Partner)
- National Composites Centre (Project Partner)
- Harrison Farms (Project Partner)
- PV3 Technologies (United Kingdom) (Project Partner)
- Domino (United Kingdom) (Project Partner)
- Loughborough University (Project Partner)
- Faradion (United Kingdom) (Project Partner)
- Futamura Chemical UK Ltd (Project Partner)
- Biomimicry Institute (Project Partner)
- C4Ware Ltd. (Project Partner)
- Johnson Matthey (United Kingdom) (Project Partner)
- Toyota Motor Corporation (Belgium) (Project Partner)
- SUPERGEN bioenergy hub (Project Partner)
- BASF (Germany) (Project Partner)
- Shell (Netherlands) (Project Partner)
- L'Oréal (France) (Project Partner)
- University of British Columbia (Project Partner)
- Consciously Aware (Project Partner)
- The Faraday Institution (Project Partner)
- RISE Research Institutes of Sweden (Project Partner)
- Fiberight (Project Partner)
- Deregallera (United Kingdom) (Project Partner)
Publications
Frka-Petesic B
(2023)
Structural Color from Cellulose Nanocrystals or Chitin Nanocrystals: Self-Assembly, Optics, and Applications.
in Chemical reviews
Frka-Petesic B
(2023)
Electrohydrodynamic convection instabilities observed in suspensions of cellulose nanocrystals.
in Cellulose (London, England)
Giri D
(2023)
Ion Size-Dependent Electrochromism in Air-Stable Napthalenediimide-Based Conjugated Polymers.
in ACS applied materials & interfaces
Hongrutai N
(2023)
Sequential deposition of FeNC - Cu tandem CO2 reduction electrocatalysts towards the low overpotential production of C2+ alcohols
in Journal of Physics: Materials
Pedersen A
(2023)
Comparative techno-economic and life-cycle analysis of precious versus non-precious metal electrocatalysts: the case of PEM fuel cell cathodes
in Green Chemistry