funding type |
European Comission |
programme |
H2020-FETOPEN-2014-2015-RIA |
acronym/
reference |
2D INK |
alternative reference |
664878 |
research group(s) |
6 - computer simulation and multiscale modeling; |
department |
Chemistry (DQ) |
execution dates |
2016-01-01 - 2018-12-31 (
36 Months )
|
abstract/
keywords |
2D-INK is targeted at developing inks of novel 2D semiconducting materials for low-cost large-area fabrication processes on insulating substrates through a new methodology, which will exceed the properties of state-of-the-art graphene- and graphene oxide based inks. Achieving this would represent an important step forward in the processing of 2D semiconducting materials and will provide the key parameters for fabricating the next generation of ultrathin electronic appliances. The inherent high-risk of 2D-INK is countered by a strongly interdisciplinary research team composed of 9 partners (8 academics + 1 SME) with demonstrated experience in their corresponding fields and with different yet highly complementary backgrounds. Therefore only together and in synergy they will be able to address the challenges of the multiple research and innovation aspects of 2D-INK that cover the entire value chain from materials design and synthesis, characterisation, formulation and processing to device implementation. In addition 2D-INK has the potential to revolutionise research on 2D semiconducting materials way beyond the current interests on synthesis (high impact), since the efficient dispersion and formulation of 2D semiconducting materials into inks enables the applications of 2D semiconducting materials over different scientific and technological disciplines, such as electronics, sensing, photonics, energy storage and conversion, spintronics, etc. Overall, 2D-INK addresses perfectly the challenge of this call as it is an archetype of an early stage, high risk visionary science and technology collaborative research project that explores radically new manufacturing and processing technologies for novel 2D semiconducting materials.
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coordinator
/local pi |
Manuel Melle-Franco |
ciceco status |
Partner |
proponent institution |
UNIVERSIDAD DEL PAIS VASCO |
partner institution(s) |
UNIVERSITAT DE VALENCIA Spain TECHNISCHE UNIVERSITAET MUENCHEN Germany KATHOLIEKE UNIVERSITEIT LEUVEN Belgium UNIVERSITAT WIEN Austria THE UNIVERSITY OF NOTTINGHAM United Kingdom Asociacion - Centro de Investigacion Cooperativa en Nanociencias - CIC NANOGUNE Spain Graphenea S.A. Spain UNIVERSIDADE DE AVEIRO Portugal
|
industrial partner(s) |
yes |
international partner(s) |
yes |
total budget |
2.962.661€
|
ciceco budget |
273.839€
|
project code |
3.89.227 |
link |
http://www.2d-ink.eu/
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Clar Rules the Electronic Properties of 2D pi-Conjugated Frameworks: Mind the GapStrutynski, K; Mateo-Alonso, A; Melle-Franco, M 2020, CHEMISTRY-A EUROPEAN JOURNAL, 26, 29, 6569-6575.
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Dibenzoanthradiquinone Building Blocks for the Synthesis of Nitrogenated Polycyclic Aromatic HydrocarbonsMartinez, JI; Mora-Fuentes, JP; Carini, M; Saeki, A; Melle-Franco, M; Mateo-Alonso, A 2020, ORGANIC LETTERS, 22, 12, 4737-4741.
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Charge transport modulation in pseudorotaxane 1D stacks of acene and azaacene derivativesGozalvez, C; Zafra, JL; Saeki, A; Melle-Franco, M; Casado, J; Mateo-Alonso, A 2019, CHEMICAL SCIENCE, 10, 9, 2743-2749.
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Giant Star-Shaped Nitrogen-Doped NanographenesMora-Fuentes, JP; Riano, A; Cortizo-Lacalle, D; Saeki, A; Melle-Franco, M; Mateo-Alonso, A 2019, ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 58, 2, 552-556.
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Hooking Together Sigmoidal Monomers into Supramolecular PolymersCarini, M; Marongiu, M; Strutynski, K; Saeki, A; Melle-Franco, M; Mateo-Alonso, A 2019, ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 58, 44, 15788-15792.
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A Wavy Two-Dimensional Covalent Organic Framework from Core-Twisted Polycyclic Aromatic HydrocarbonsMartinez-Abadia, M; Stoppiello, CT; Strutynski, K; Lerma-Berlanga, B; Marti-Gastaldo, C; Saeki, A; Melle-Franco, M; Khlobystov, AN; Mateo-Alonso, A 2019, JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, 141, 36, 14403-14410.
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Monodisperse N-Doped Graphene Nanoribbons Reaching 7.7 Nanometers in LengthCortizo-Lacalle, D; Mora-Fuentes, JP; Strutynski, K; Saeki, A; Melle-Franco, M; Mateo-Alonso, A 2018, ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 57, 3, 703-708.
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A thiadiazole-capped nanoribbon with 18 linearly fused ringsCortizo-Lacalle, D; Gozalvez, C; Franco, MM; Mateo-Alonso, A 2018, NANOSCALE, 10, 24, 11297-11301.
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High conductance values in pi-folded molecular junctionsCarini, M; Ruiz, MP; Usabiaga, I; Fernandez, JA; Cocinero, EJ; Melle-Franco, M; Diez-Perez, I; Mateo-Alonso, A 2017, NATURE COMMUNICATIONS, 8,
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Twisted Aromatic Frameworks: Readily Exfoliable and Solution-Processable Two-Dimensional Conjugated Microporous PolymersMarco, AB; Cortizo-Lacalle, D; Perez-Miqueo, I; Valenti, G; Boni, A; Plas, J; Strutynski, K; De Feyter, S; Paolucci, F; Montes, M; Khlobystov, AN; Melle-Franco, M; Mateo-Alonso, A 2017, ANGEWANDTE CHEMIE-INTERNATIONAL EDITION, 56, 24, 6946-6951.
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K-Conjugated DibenzoazahexacenesAntonicelli, G; Gozalvez, C; Abcabal, A; Melle-Franco, M; Hueso, LE; Mateo-Alonso, A 2016, ORGANIC LETTERS, 18, 18, 4694-4697.
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