Summary
This project aims for revolutionary energy filtering nano-devices for information and communications technology (ICT). It is at the intersection of phononics, photonics, nanoscale electro-thermal devices and molecular engineering. By building new energy filtering devices down to molecular scales we aim to generate new knowledge and understanding of the electronic, phononic and near-field energy/heat fluxes at the fundamental limits of nano-scale energy management, and to demonstrate novel proof-of-concept non-equilibrium phonon engineered electro-thermal devices in real applications. The efficient nano-scale thermal management necessitate developing new theoretical and experimental tools for understanding and mastering the individual non-equilibrium energy/particle channels and inter-channel couplings. Control of the physical mechanisms behind non-equilibrium electronic energy filtering effects will be firstly addressed by non-linear transport in molecular junctions by developing new research tools that combine state-of-the-art molecular synthesis, bolometers, scanning probe microscopy technologies and theoretical modelling. In parallel with the molecular bottom-up approach, we will work with scalable thermionic nano-junctions, which not only have great technological potential of their own but also serve as a model system for the molecular devices. By employing non-linear out of equilibrium electro-thermal effects in molecular and scaled-down junction systems, we pursue the realization of proof-of-concept ICT devices utilizing these technologies within the time span of the project. This project will combine synergies in theory, experiment and technology-development covering different fields from chemistry to electronics. The project partners, who are leaders in their respective fields, form a consortium that is uniquely positioned to achieve the ambitious objectives.
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| Web resources: | https://cordis.europa.eu/project/id/766853 |
| Start date: | 01-01-2018 |
| End date: | 30-06-2022 |
| Total budget - Public funding: | 2 919 037,50 Euro - 2 919 037,00 Euro |
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Original description
This project aims for revolutionary energy filtering nano-devices for information and communications technology (ICT). It is at the intersection of phononics, photonics, nanoscale electro-thermal devices and molecular engineering. By building new energy filtering devices down to molecular scales we aim to generate new knowledge and understanding of the electronic, phononic and near-field energy/heat fluxes at the fundamental limits of nano-scale energy management, and to demonstrate novel proof-of-concept non-equilibrium phonon engineered electro-thermal devices in real applications. The efficient nano-scale thermal management necessitate developing new theoretical and experimental tools for understanding and mastering the individual non-equilibrium energy/particle channels and inter-channel couplings. Control of the physical mechanisms behind non-equilibrium electronic energy filtering effects will be firstly addressed by non-linear transport in molecular junctions by developing new research tools that combine state-of-the-art molecular synthesis, bolometers, scanning probe microscopy technologies and theoretical modelling. In parallel with the molecular bottom-up approach, we will work with scalable thermionic nano-junctions, which not only have great technological potential of their own but also serve as a model system for the molecular devices. By employing non-linear out of equilibrium electro-thermal effects in molecular and scaled-down junction systems, we pursue the realization of proof-of-concept ICT devices utilizing these technologies within the time span of the project. This project will combine synergies in theory, experiment and technology-development covering different fields from chemistry to electronics. The project partners, who are leaders in their respective fields, form a consortium that is uniquely positioned to achieve the ambitious objectives.Status
CLOSEDCall topic
FETOPEN-01-2016-2017Update Date
27-04-2024
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