Summary
Organic conductive polymers are gaining increased interest each day due to their broad applications, low cost and ease of manipulation. Their potential to develop new products that will transform the daily lives of people in Europe and around the world is significant. Among the application areas with the highest potential, smart textiles provide one of the most futuristic and innovative potential products. At present, a conducting polymeric material that can be use directly as textile does not exist primarily a consequence of the poor (brittle) materials properties of conducting polymers. Any such products are created by coating of the conductive material onto the textile or tissue. However the ability to use polymers to create wearable electronics has transformative potential to become a disruptive technology. This proposal aims to create a conductive polymer with elastomeric properties such that it has enhanced materials properties and can therefore be applied directly as scaffold for smart textile creation. To make the polymeric scaffold, the nucleophilic thiol-yne “click” reaction between an activated alkyne and thiol will be used. This pathway will enable retention of the electrical conductivity while presenting the possibility to tune the mechanical properties by choosing the stereochemistry (E/Z) of the unsaturated bond that is formed. Moreover, the elastomeric nature of the resultant materials, presents a unique opportunity to create conductive elastomers that can be easily applied to wearable electronics: able to record electrical signals such as heartbeats or muscular contractions. The project is going to combining the organic synthesis and click chemistry expertise of Mantione with that of conducting polymer synthesis and characterization of Prof. Hadziioannou. The planned secondment is aiming to allied to the expertise of Prof. Malliaras (Cambridge, UK) in wearable electronics: biotest the materials and practically create the textile.
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| Web resources: | https://cordis.europa.eu/project/id/838171 |
| Start date: | 01-06-2019 |
| End date: | 31-05-2021 |
| Total budget - Public funding: | 184 707,84 Euro - 184 707,00 Euro |
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Original description
Organic conductive polymers are gaining increased interest each day due to their broad applications, low cost and ease of manipulation. Their potential to develop new products that will transform the daily lives of people in Europe and around the world is significant. Among the application areas with the highest potential, smart textiles provide one of the most futuristic and innovative potential products. At present, a conducting polymeric material that can be use directly as textile does not exist primarily a consequence of the poor (brittle) materials properties of conducting polymers. Any such products are created by coating of the conductive material onto the textile or tissue. However the ability to use polymers to create wearable electronics has transformative potential to become a disruptive technology. This proposal aims to create a conductive polymer with elastomeric properties such that it has enhanced materials properties and can therefore be applied directly as scaffold for smart textile creation. To make the polymeric scaffold, the nucleophilic thiol-yne “click” reaction between an activated alkyne and thiol will be used. This pathway will enable retention of the electrical conductivity while presenting the possibility to tune the mechanical properties by choosing the stereochemistry (E/Z) of the unsaturated bond that is formed. Moreover, the elastomeric nature of the resultant materials, presents a unique opportunity to create conductive elastomers that can be easily applied to wearable electronics: able to record electrical signals such as heartbeats or muscular contractions. The project is going to combining the organic synthesis and click chemistry expertise of Mantione with that of conducting polymer synthesis and characterization of Prof. Hadziioannou. The planned secondment is aiming to allied to the expertise of Prof. Malliaras (Cambridge, UK) in wearable electronics: biotest the materials and practically create the textile.Status
CLOSEDCall topic
MSCA-IF-2018Update Date
28-04-2024
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