Objectif This project will take inspiration from biomineralisation to achieve exceptional, dynamic control over crystallisation processes. Understanding the fundamental mechanisms which govern crystallisation promises the ability to inhibit or promote crystallisation as desired, and to tailor the properties of crystalline materials towards a huge range of applications. Biomineralisation provides a perfect precedent for this approach, where organisms achieve control currently unparalleled in synthetic systems. This is achieved because mineralisation occurs within controlled environments in which an organism can interact with the nascent mineral.Thanks to recent advances in microfabrication techniques and analytical methods we finally have the tools required to bring such control to the laboratory. DYNAMIN will exploit microfluidic and confined systems to study and interact with crystallisation processes with outstanding spatial and temporal resolution. Flowing droplet devices will be coupled to synchrotron techniques to investigate and control nucleation, using soluble additives and nucleating particles to direct the crystallisation pathway. Static chambers will be used to interact with crystallisation processes over longer length and time scales to achieve spatio-temporal control to rival that in biomineralisation, while a unique confined system – titania nanotubes – will enable the study and control of organic-mediated mineralisation, using fresh reagents and proteinases to interact with the process. Finally, a key biogenic strategy will provide the inspiration to develop a simple and potentially general method to trigger and control the transformation of amorphous precursor phases to single crystal products.This will generate a new framework for studying and controlling crystallisation processes, where these new skills will find applications in sectors ranging from the Chemical Industry, to Healthcare, Advanced Materials, Formulated Products and the Environment. Champ scientifique engineering and technologymaterials engineeringcrystals Mots‑clés Crystallization Biomineralization Calcium carbonate Bio-inspired Microfluidic Programme(s) H2020-EU.1.1. - EXCELLENT SCIENCE - European Research Council (ERC) Main Programme Thème(s) ERC-2017-ADG - ERC Advanced Grant Appel à propositions ERC-2017-ADG Voir d’autres projets de cet appel Régime de financement ERC-ADG - Advanced Grant Institution d’accueil UNIVERSITY OF LEEDS Contribution nette de l'UE € 2 632 375,00 Adresse WOODHOUSE LANE LS2 9JT Leeds Royaume-Uni Voir sur la carte Région Yorkshire and the Humber West Yorkshire Leeds Type d’activité Higher or Secondary Education Establishments Liens Contacter l’organisation Opens in new window Site web Opens in new window Participation aux programmes de R&I de l'UE Opens in new window Réseau de collaboration HORIZON Opens in new window Coût total € 2 632 375,00 Bénéficiaires (1) Trier par ordre alphabétique Trier par contribution nette de l'UE Tout développer Tout réduire UNIVERSITY OF LEEDS Royaume-Uni Contribution nette de l'UE € 2 632 375,00 Adresse WOODHOUSE LANE LS2 9JT Leeds Voir sur la carte Région Yorkshire and the Humber West Yorkshire Leeds Type d’activité Higher or Secondary Education Establishments Liens Contacter l’organisation Opens in new window Site web Opens in new window Participation aux programmes de R&I de l'UE Opens in new window Réseau de collaboration HORIZON Opens in new window Coût total € 2 632 375,00