Description du projet
Atteindre de nouveaux sommets pour le traitement des signaux en térahertz
En tant qu’outil clé pour la prochaine génération de systèmes de communication sans fil, les communications dans la bande de fréquences térahertz (THz) sont sur le devant de la scène. La gamme térahertz offre un énorme potentiel inexploité pour de nombreuses applications de nouvelle génération, telles que les communications sans fil, la détection, la sécurité, l’imagerie médicale et bien plus encore. Le projet ELEPHANT, financé par l’UE, s’éloignera des plateformes électro-photoniques actuelles pour créer une plateforme intégrée innovante qui transportera et traitera les fréquences THz avec un minimum de pertes et de manière flexible, dans le domaine optique, permettant ainsi la diffusion efficiente des fréquences THz sur de grandes distances. Le projet s’appuie sur de précédents résultats à la pointe de l’innovation concernant les blocs de traitement de signaux photoniques avec des bandes passantes en THz, à l’aide de nanofils photoniques compacts en silicone (10 s de µm), ainsi que la récente démonstration de modulateurs plasmoniques permettant des vitesses de l’ordre de 500 GHz, la solution la plus rapide à ce jour.
Objectif
The ELEPHANT project aims at combining the best of four worlds by bringing together the fastest electronics, photonics, plasmonics and antennas to create a novel enabling technology for future THz signal processing.
The THz range has a tremendous untapped potential for a breadth of applications, as next-generation wireless communications, sensing, security, medical imaging, and more. However, efficient transport and processing of THz signals is a major challenge to this date, as at those frequencies electronic circuits are inherently limited by high dispersion and material losses. As a consequence, current approaches still rely on low-efficiency discrete components, which suffer from limited power, high losses and very high costs. While photonics allows low-loss transport of THz frequencies over large distances and broadband processing, today’s electronic-photonic platforms do not offer the required conversion speeds. Current efforts using organic materials have not proven sufficient stability and scalability.
I plan to solve the challenge of THz signal processing by creating a novel integrated THz platform that allows to convert THz signals to the optical domain efficiently and with high fidelity, and to process them using a low-loss photonic processing core with THz bandwidth.
The project fully builds on my cutting-edge results on photonic signal processing blocks with THz bandwidths using compact (10s µm-long) silicon photonics nanowires, and my recent demonstration of plasmonic modulators offering 500 GHz speeds, the fastest to date. I will create novel architectures suitable for analog processing and realize them in a scalable manner on bipolar CMOS platforms, together with THz antennas for wireless interfacing, and high-speed amplifiers to achieve the signal powers needed in real-world applications.
The new platform will impact all the crucial THz fields, and it will be put to the test by creating the first photonic-wireless THz beamforming transceiver.
Champ scientifique
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectronic engineeringsignal processing
- natural scienceschemical sciencesinorganic chemistrymetalloids
- engineering and technologyelectrical engineering, electronic engineering, information engineeringinformation engineeringtelecommunicationsradio technology
- engineering and technologymedical engineeringdiagnostic imaging
Programme(s)
Thème(s)
Régime de financement
ERC-STG - Starting GrantInstitution d’accueil
10623 Berlin
Allemagne