SubsidieMeestersAtypical Liquid Crystal Elastomers: from Materials Innovation to Scalable processing and Transformative applications
ALCEMIST aims to revolutionize engineering by creating biocompatible, cost-effective liquid crystal elastomers (LCEs) that combine passive and active functionalities for diverse innovative applications.
Projectdetails
Introduction
ALCEMIST challenges the conventional engineering mindset where passive static components (beams, wires, joints) are driven by active dynamic ones (motors, dampers, sensors); our innovative materials enable the combined functionality in a single component. This bold ambition is feasible because our research will unlock the full potential of liquid crystal elastomers (LCEs), unique responsive materials that reversibly change shape, colour, adhesive or damping properties, triggered by stimuli like heat, light, humidity or strain.
Sustainable Materials Platform
We propose a radically new sustainable materials platform based on polysaccharides, functionalising precursors such that anyone—using click chemistry—can make LCEs that are powerful yet biocompatible and biodegradable, at one tenth of the cost of state-of-the-art LCEs.
Re-processable and Re-usable LCEs
Further, using bond-exchange chemistry, ALCEMIST LCEs will be re-processable and re-usable. We also present a ground-breaking processing approach based on flow patterning to make large-scale LCEs of complex shapes and actuation modes.
Collaborative Expertise
The synergy of three perfectly complementary and highly productive scientists, each a recognised leader in their field, enables this transformative approach to making atypical LCEs.
Industrial Upscaling and Applications
As all our methods are ideal for industrial upscaling, we will also demonstrate the yet untapped potential of LCEs when they are applied in atypical contexts, totally different from the current mainstream academic focus. These applications range from:
- Adhesives that can be reversibly debonded on demand.
- Sun-powered adaptive building elements which save energy and improve indoor atmosphere.
- Microhearts and peristaltic vasculature that can remove the growth limits of lab-grown organs.
- Smart threads that give doctors critical feedback on suture tension when conducting robotic surgery.
Conclusion
By overthrowing multiple conventions in the ways LCEs are synthesised, studied and engineered, ALCEMIST will enable and stimulate new lines of research, basic and applied, across large communities.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 8.477.534 |
| Totale projectbegroting | € 8.477.534 |
Tijdlijn
| Startdatum | 1-3-2025 |
| Einddatum | 28-2-2031 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- UNIVERSITE DU LUXEMBOURGpenvoerder
- THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE
- UNIVERSIDADE NOVA DE LISBOA
Land(en)
Vergelijkbare projecten binnen European Research Council
| Project | Regeling | Bedrag | Jaar | Actie |
|---|---|---|---|---|
REVEALing complex strain patterns and dangerous loads using cholesteric liquid crystal elastomersThe REVEAL project aims to develop scalable Cholesteric Liquid Crystal Elastomer sheets and fibers for high-resolution 2D strain sensing to enhance structural health monitoring and smart textiles. | ERC Proof of... | € 150.000 | 2022 | Details |
Engineering homeostasis into living materialsThe STEADY project aims to engineer homeostasis into living materials by developing modular sensors, controllers, and actuators to enhance their adaptability and resilience to environmental changes. | ERC Advanced... | € 2.500.000 | 2022 | Details |
3D Printed, Bioinspired, Soft-Matter Electronics based on Liquid Metal Composites: Eco-Friendly, Resilient, Recyclable, and RepairableLiquid3D aims to revolutionize electronics by developing soft, self-healing, and recyclable devices using innovative Liquid Metal composites for sustainable and interactive technology. | ERC Consolid... | € 2.781.215 | 2023 | Details |
Additive Micromanufacturing: Multimetal Multiphase Functional ArchitecturesAMMicro aims to develop robust 3D MEMS devices using localized electrodeposition and advanced reliability testing to enhance damage sensing and impact protection for diverse applications. | ERC Starting... | € 1.498.356 | 2023 | Details |
Liquid Crystals in Flow: A New Era in Sensing and DiagnosticsThis project aims to develop highly sensitive, label-free liquid crystal-based microfluidic sensors by investigating the effects of soft interfaces and chemical heterogeneity on flow dynamics and optical properties. | ERC Starting... | € 1.500.000 | 2022 | Details |
REVEALing complex strain patterns and dangerous loads using cholesteric liquid crystal elastomers
The REVEAL project aims to develop scalable Cholesteric Liquid Crystal Elastomer sheets and fibers for high-resolution 2D strain sensing to enhance structural health monitoring and smart textiles.
Engineering homeostasis into living materials
The STEADY project aims to engineer homeostasis into living materials by developing modular sensors, controllers, and actuators to enhance their adaptability and resilience to environmental changes.
3D Printed, Bioinspired, Soft-Matter Electronics based on Liquid Metal Composites: Eco-Friendly, Resilient, Recyclable, and Repairable
Liquid3D aims to revolutionize electronics by developing soft, self-healing, and recyclable devices using innovative Liquid Metal composites for sustainable and interactive technology.
Additive Micromanufacturing: Multimetal Multiphase Functional Architectures
AMMicro aims to develop robust 3D MEMS devices using localized electrodeposition and advanced reliability testing to enhance damage sensing and impact protection for diverse applications.
Liquid Crystals in Flow: A New Era in Sensing and Diagnostics
This project aims to develop highly sensitive, label-free liquid crystal-based microfluidic sensors by investigating the effects of soft interfaces and chemical heterogeneity on flow dynamics and optical properties.
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Living Therapeutic and Regenerative Materials with Specialised Advanced Layers
Developing skin-inspired engineered living materials with sensing and regenerative functions for therapeutic and protective applications through multicellular consortia and genetic control.
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Enlisting synthetic fungal-bacterial consortia to produce multi-cellular mycelium-based ELMs with computational capability
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Bioinspired cellular actuators
BiCeps aims to create robust, muscle-inspired actuators using multi-material additive manufacturing to revolutionize mechanical motion and replace traditional motors across various sectors.