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3D Biofabricated high-perfoRmance dna-carbon nanotube dIgital electroniCKSbroad

3D-BRICKS · Horizon Europe grant · 2023-05-01–2026-04-30

EC contribution

€3,570,259

Total cost

€3,570,259

Beneficiaries

12
About the data

Source: CORDIS (official EU open data), Horizon Europe. Framework HORIZON · call HORIZON-EIC-2022-PATHFINDEROPEN-01 · scheme HORIZON-EIC · topic HORIZON-EIC-2022-PATHFINDEROPEN-01-01. CORDIS record →

Objective

Silicon-based CMOS technology is approaching its performance limits, but the demand for more powerful computers — driven by rapid advances in applications such as the Internet of Things, big data and artificial intelligence (AI) — remains. The discovery of various nanomaterials provides new opportunities to further develop information processing technology. Carbon nanotubes (CNTs) have, in particular, demonstrated excellent properties as a channel material in transistors. Computers based on CNT field-effect transistors (FETs) have been theoretically predicted to provide a power-performance improvement of ten times over computers based on Si-CMOS technology. However, the fabrication of high-performance CNT-nanoelectronics, and the realization of the full potential of CNTs, is highly challenging. A technological revolution would be a reliable approach to fabricate a new family of CNT-based devices that could enable aligned arrangement of the nanotubes avoiding the critical steps related to nanolithography. In particular, biofabrication using DNA-templated CNT arrays FETs has been demonstrated to further scale the alignment of CNTs within the FETs well beyond standard lithographic feasibility. 3D-BRICKS will raise this concept of integrated self-assembly CNT-nanocircuits to a completely new level by moving towards the third dimension. Indeed, the versatility of DNA nanotechnology will be the root for conceiving 3-dimensional (3D) CNT-FETs and CNT-nonvolatile memories. DNA nanotechnology will also enable to complement the CNT deposition with metallic connections, hence realizing a working circuit. This will reduce the foot-print of the final device while enhancing its efficiency, hence providing a breakthrough solution to realize the next-generation nanoelectronics. Furthermore, automated droplet-based CNT-DNA assembly, selective sorting and deposition based on assembly quality, will be an enabling technology towards upscaling production. Our approach will enable the production of scalable biotemplated electronics that can be extended to multiple applications such as metamaterials, sensors, optoelectronics, and others.

Beneficiaries (12)

OrganisationCountryRoleEC contributionSME
FONDAZIONE ISTITUTO ITALIANO DI TECNOLOGIA IT coordinator €466,875
TALLINNA TEHNIKAÜLIKOOL EE participant €535,500
UNIVERSITY OF HAMBURG DE participant €499,000
KARLSRUHER INSTITUT FUER TECHNOLOGIE DE participant €403,062
UNIVERSITAET LEIPZIG DE participant €372,500
UNIVERSITEIT ANTWERPEN BE participant €350,000
FUNDACIO INSTITUT CATALA DE NANOCIENCIA I NANOTECNOLOGIA ES participant €298,196
KERR S.R.L IT participant €270,000 Yes
UNIVERSITA DEGLI STUDI DI MODENA E REGGIO EMILIA IT participant €203,250
CNT INNOVATION BE participant €171,875 Yes
University of Fribourg CH associatedPartner
UNIVERSITE DE FRIBOURG CH associatedPartner

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