HyperSpectral Terahertz neAR-field nanoscope exploiting miniaturized frequency-combs

ERC (European Research Council)HORIZON-ERC-POCID: 101081567
EC Contribution
€1,500
Consortium Size
1 orgs
Start Year
2022
Summary

‘STAR’ aims to increase the technology readiness level of the state-of-the-art graphene-integrated, miniaturized frequency comb (FC) quantum cascade laser (QCL), operating at terahertz (THz) frequencies, devised under the ERC consolidator grant ‘SPRINT’, and develop a detector-less sensing/imaging demonstrator apt to the translation of this technology to industrial end-users. The focus is on providing a compact, low-cost, hyperspectral, nanoscale imaging system, which creates amplitude- and phase-resolved images, employing the not-invasive broadband THz-frequency light of a metrological frequency-comb source, without making use of an external detector. This nanoscope ensures 40-100 nm spatial resolution, >100 times smaller than the THz free-space wavelength, coherent detection and mapping of the THz optical response of materials over the continuous 2-5 THz bandwidth provided by a fully stabilized THz QCL FC, with noise-equivalent-power <10pW/√Hz and fast (<ms/pixel) acquisition rates, far exceeding the performances of commercial time-domain spectroscopy near-field systems.Specific objectives are to manufacture a compact, portable and user-friendly THz hyperspectral nanoscope, validate its core technology with commercial end-users and at trade-shows and evaluate opportunities for THz FC self-detection nanoscopy, identifying novel end-user applications, with a detailed market, IPR and regulatory compliance study. By the end of this programme, I plan to identify a solid exploitation route by directly interacting with THz instrument producers and with targeted commercial end-users.Pushing forward a solid commercial exploitation route, STAR prospects new directions and long-term impacts on many interdisciplinary fields crossing engineering, biology, medicine, cultural heritage, material science and quantum technology, and in a frontier frequency domain where electronics and photonics find a fascinating convergence.

Consortium (1)

Project Results (3)

Source: CORDIS, the EU research results database.

Publications (3)
Terahertz Plasmon Polaritons in Large Area Bi2Se3 Topological Insulators
Advanced Optical Materials· 2024DOI
Valentino Pistore, Leonardo Viti, Chiara Schiattarella, Elisa Riccardi, Craig S Knox, Ahmet Yagmur, Joel J Burton, Satoshi Sasaki, A Giles Davies, Edmund H Linfield, Joshua R Freeman, Miriam S Vitiello
Holographic Nano‐Imaging of Terahertz Dirac Plasmon Polaritons in Topological Insulator Antenna Resonators
Small· 2023DOI
Valentino Pistore, Leonardo Viti, Chiara Schiattarella, Zhengtianye Wang, Stephanie Law, Oleg Mitrofanov, Miriam S Vitiello
Optical Materials Express
Optical materials express (2023): 3045–3050. doi:10.1364/OME.504097· 2023DOI
Vitiello; Miriam Serena (a).