Summary
Self healing polymers, i.e., materials which the ability to repair themselves, have emerged as an attractive alternative to traditional materials due to the advantages they offer to society in terms of durability, reliability and cost and energy efficiencies. A fruitful approach towards these novel materials is based on the introduction of supramolecular cross-links into polymer frameworks, which, due to their reversible and dynamic nature, can be dissociated and reconnected multiple times to heal the damaged area. However, polymer toughness and autonomous healing exhibit an inverse relationship and, for practical reasons, the healing process must be activated in conditions that are different from the working conditions, or otherwise the material becomes too soft. Such activation is typically carried out through thermal heating, which accelerates the dynamics of the non-covalent bonds and enhances polymer chain diffusion.
In LightHeal we plan to make a groundbreaking impact in the field of dynamic polymer networks by developing phtotoswitchable supramolecular cross-links that exploit the extraordinary attributes of Light as an external stimulus. Concretely, we want to be able to switch on/off cooperative noncovalent cross-links in polymer networks, so that the material can reversibly alternate, on demand, between a mechanically tough state and a soft, healable state. Moreover, we want to achieve such control with spatial precision, temporal precision, and wavelength orthogonality. For such goal, we will combine the knowledge of the host group in G-quadruplex polymer networks with the experience of the candidate in state-of-the art azobenzene photoswitches.
LightHeal introduces fundamental challenges and unprecedented approaches in the expanding field of stimuli-responsive polymer materials with “smart” functionalities, and constitutes the best research scenario for the candidate to learn from different fields and further develop his career.
In LightHeal we plan to make a groundbreaking impact in the field of dynamic polymer networks by developing phtotoswitchable supramolecular cross-links that exploit the extraordinary attributes of Light as an external stimulus. Concretely, we want to be able to switch on/off cooperative noncovalent cross-links in polymer networks, so that the material can reversibly alternate, on demand, between a mechanically tough state and a soft, healable state. Moreover, we want to achieve such control with spatial precision, temporal precision, and wavelength orthogonality. For such goal, we will combine the knowledge of the host group in G-quadruplex polymer networks with the experience of the candidate in state-of-the art azobenzene photoswitches.
LightHeal introduces fundamental challenges and unprecedented approaches in the expanding field of stimuli-responsive polymer materials with “smart” functionalities, and constitutes the best research scenario for the candidate to learn from different fields and further develop his career.
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| Web resources: | https://cordis.europa.eu/project/id/101150870 |
| Start date: | 01-12-2024 |
| End date: | 30-11-2026 |
| Total budget - Public funding: | - 165 312,00 Euro |
Cordis data
Original description
Self healing polymers, i.e., materials which the ability to repair themselves, have emerged as an attractive alternative to traditional materials due to the advantages they offer to society in terms of durability, reliability and cost and energy efficiencies. A fruitful approach towards these novel materials is based on the introduction of supramolecular cross-links into polymer frameworks, which, due to their reversible and dynamic nature, can be dissociated and reconnected multiple times to heal the damaged area. However, polymer toughness and autonomous healing exhibit an inverse relationship and, for practical reasons, the healing process must be activated in conditions that are different from the working conditions, or otherwise the material becomes too soft. Such activation is typically carried out through thermal heating, which accelerates the dynamics of the non-covalent bonds and enhances polymer chain diffusion.In LightHeal we plan to make a groundbreaking impact in the field of dynamic polymer networks by developing phtotoswitchable supramolecular cross-links that exploit the extraordinary attributes of Light as an external stimulus. Concretely, we want to be able to switch on/off cooperative noncovalent cross-links in polymer networks, so that the material can reversibly alternate, on demand, between a mechanically tough state and a soft, healable state. Moreover, we want to achieve such control with spatial precision, temporal precision, and wavelength orthogonality. For such goal, we will combine the knowledge of the host group in G-quadruplex polymer networks with the experience of the candidate in state-of-the art azobenzene photoswitches.
LightHeal introduces fundamental challenges and unprecedented approaches in the expanding field of stimuli-responsive polymer materials with “smart” functionalities, and constitutes the best research scenario for the candidate to learn from different fields and further develop his career.
Status
SIGNEDCall topic
HORIZON-MSCA-2023-PF-01-01Update Date
12-03-2024
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