ConTROL SIGNED
Charge-TRansfer states for high-performance Organic eLectronics
Total Cost €
0EC-Contrib. €
0Partnership
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0ConTROL project word cloud
Explore the words cloud of the ConTROL project. It provides you a very rough idea of what is the project "ConTROL" about.
Project "ConTROL" data sheet
The following table provides information about the project.
| Coordinator |
UNIVERSITEIT HASSELT
Organization address contact info |
| Coordinator Country | Belgium [BE] |
| Total cost | 2˙369˙150 € |
| EC max contribution | 2˙369˙150 € (100%) |
| Programme |
1. H2020-EU.1.1. (EXCELLENT SCIENCE - European Research Council (ERC)) |
| Code Call | ERC-2019-COG |
| Funding Scheme | ERC-COG |
| Starting year | 2020 |
| Duration (year-month-day) | from 2020-07-01 to 2025-06-30 |
Partnership
Take a look of project's partnership.
| # | ||||
|---|---|---|---|---|
| 1 | UNIVERSITEIT HASSELT | BE (HASSELT) | coordinator | 2˙369˙150.00 |
Map
Project objective
Thin films comprising a blend of electron donating (D) and electron accepting (A) molecules are ubiquitous in organic electronic devices. At the D-A interfaces, intermolecular charge-transfer (CT) states form, in which an electron is transferred from D to A. Electrical doping (p- and n-type) involves ground-state CT from dopant to host and results in increased conductivities of the host organic semiconductor. Furthermore, the performances of organic solar cells, photodetectors and light emitting diodes depend crucially on D-A interfaces where the CT state is an excited state, mediating between photons and free charge carriers. New applications of intermolecular CT states, such as transparent conductors, artificial synapses, biosensors, organic persistent luminescent materials and low cost narrowband near-infrared sensors have emerged in the past years, and there is clearly potential for additional innovation. However, current progress is hampered by a lack of understanding of the fundamental properties of intermolecular CT states and their decay and dissociation mechanisms. ConTROL aims to fill this knowledge gap and link device performance to molecular parameters of D-A interfaces. Electro-optical properties will be tuned by molecular design and appropriate D-A selection, as well as by weak and strong interactions with the opto-electronic device’s optical cavity. The knowledge generated will not merely result in improved performance of existing organic electronic devices, but new avenues and novel exciting applications of intermolecular CT states will be demonstrated.
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