Summary
Modern technologies increasingly require smart and sustainable materials that adapt to their operating conditions in functional devices, such as those for efficient energy production and nanorobotics. Their development requires controlling complex material functions in response to external stimuli. While molecular machines demonstrated remarkable potential in a wide range of stimuli-responsive functions, this remains a challenge in the solid state, hampering their use in functional devices. Overcoming this necessitates an amphidynamic platform that is ordered yet permits molecular motion without compromising stimuli-responsiveness, while offering the ease of processing for device fabrication. SmartHyMat will address this enduring challenge by relying on the unparalleled capacity of hybrid halide perovskites to act as unique scaffolds for stimuli-responsive systems. These soft yet crystalline materials recently emerged as one of the leading semiconductors for thin-film optoelectronics, featuring mixed ionic-electronic conductivities and extraordinary performances in solution-processable devices. While their operational stability can be enhanced by incorporating organic moieties, their functionality remains limited to electronically inactive off-the-shelf materials. This project will realize the innovative potential of hybrid perovskites in adaptive nanotechnologies through molecular design, synthesis, and characterization of stimuli-responsive systems in hybrid solid-state architectures. Their potential will be demonstrated in unprecedented smart devices for power generation, memory, and actuation relevant for automation and nanorobotics. This will involve optoelectronic, such as smart solar cells, as well as optoionic devices exploiting mixed conductivities, including artificial synapses and neuromuscular junctions. The focus will be on environmentally friendly materials, setting the stage for an entirely new generation of smart and sustainable nanotechnologies.
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| Web resources: | https://cordis.europa.eu/project/id/101114653 |
| Start date: | 01-09-2024 |
| End date: | 31-08-2029 |
| Total budget - Public funding: | 2 123 241,00 Euro - 2 123 241,00 Euro |
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Original description
Modern technologies increasingly require smart and sustainable materials that adapt to their operating conditions in functional devices, such as those for efficient energy production and nanorobotics. Their development requires controlling complex material functions in response to external stimuli. While molecular machines demonstrated remarkable potential in a wide range of stimuli-responsive functions, this remains a challenge in the solid state, hampering their use in functional devices. Overcoming this necessitates an amphidynamic platform that is ordered yet permits molecular motion without compromising stimuli-responsiveness, while offering the ease of processing for device fabrication. SmartHyMat will address this enduring challenge by relying on the unparalleled capacity of hybrid halide perovskites to act as unique scaffolds for stimuli-responsive systems. These soft yet crystalline materials recently emerged as one of the leading semiconductors for thin-film optoelectronics, featuring mixed ionic-electronic conductivities and extraordinary performances in solution-processable devices. While their operational stability can be enhanced by incorporating organic moieties, their functionality remains limited to electronically inactive off-the-shelf materials. This project will realize the innovative potential of hybrid perovskites in adaptive nanotechnologies through molecular design, synthesis, and characterization of stimuli-responsive systems in hybrid solid-state architectures. Their potential will be demonstrated in unprecedented smart devices for power generation, memory, and actuation relevant for automation and nanorobotics. This will involve optoelectronic, such as smart solar cells, as well as optoionic devices exploiting mixed conductivities, including artificial synapses and neuromuscular junctions. The focus will be on environmentally friendly materials, setting the stage for an entirely new generation of smart and sustainable nanotechnologies.Status
SIGNEDCall topic
ERC-2023-STGUpdate Date
12-03-2024
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