SWIRL | Short-wave Infrared Light emitters based on Colloidal Quantum Dot Technology

Summary
Optical sensing and imaging has evolved from taking digital images to a powerful metrology, imaging and data acquisition
technique by expanding the spectral coverage from the visible to the short-wave infrared (SWIR). SWIR sensing and
imaging is the cornerstone of advanced imaging techniques for 3D visualization, night vision, imaging though adverse
weather conditions, biomedical imaging, spectroscopy for food quality and health monitoring, just to name a few. The huge
market size of such applications, especially by entering volume markets including consumer electronics and automotive, has
led to the first commercial appearances of low cost CMOS compatible SWIR photodetectors and image sensors. Yet for the
realization of the afore-mentioned technologies the optical source is an equally important and crucial component to be
considered at system level. To date, there is a lack of infrared optical sources that are CMOS compatible, low-cost with
competitive performance over the standard costly epitaxial III-V light emitters. Moreover high cost and epitaxial growth
manufacturing processes have limited the size and form factor of those sources to small and rigid elements preventing their
use as high power and large area illumination sources. SWIRL will undertake this challenge to develop high performance
low-cost SWIR optical sources with tunable emission peaks and spectral bandwidths across the eye-safety SWIR window,
exploiting colloidal quantum dot technology. By leveraging engineering at the nanoscale and solution processed materials
we will develop in TRL4/5 SWIR optical emitters that are low-cost, high efficiency, even rivalling their epitaxial counterparts,
and spectrally versatile across the SWIR. We will further demonstrate their use in key applications related to automotive
industry as optical sources for active SWIR imaging and in-cabin monitoring in the eye-safety infrared window.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101069217
Start date: 01-09-2022
End date: 29-02-2024
Total budget - Public funding: - 150 000,00 Euro
Cordis data

Original description

Optical sensing and imaging has evolved from taking digital images to a powerful metrology, imaging and data acquisition
technique by expanding the spectral coverage from the visible to the short-wave infrared (SWIR). SWIR sensing and
imaging is the cornerstone of advanced imaging techniques for 3D visualization, night vision, imaging though adverse
weather conditions, biomedical imaging, spectroscopy for food quality and health monitoring, just to name a few. The huge
market size of such applications, especially by entering volume markets including consumer electronics and automotive, has
led to the first commercial appearances of low cost CMOS compatible SWIR photodetectors and image sensors. Yet for the
realization of the afore-mentioned technologies the optical source is an equally important and crucial component to be
considered at system level. To date, there is a lack of infrared optical sources that are CMOS compatible, low-cost with
competitive performance over the standard costly epitaxial III-V light emitters. Moreover high cost and epitaxial growth
manufacturing processes have limited the size and form factor of those sources to small and rigid elements preventing their
use as high power and large area illumination sources. SWIRL will undertake this challenge to develop high performance
low-cost SWIR optical sources with tunable emission peaks and spectral bandwidths across the eye-safety SWIR window,
exploiting colloidal quantum dot technology. By leveraging engineering at the nanoscale and solution processed materials
we will develop in TRL4/5 SWIR optical emitters that are low-cost, high efficiency, even rivalling their epitaxial counterparts,
and spectrally versatile across the SWIR. We will further demonstrate their use in key applications related to automotive
industry as optical sources for active SWIR imaging and in-cabin monitoring in the eye-safety infrared window.

Status

SIGNED

Call topic

ERC-2022-POC1

Update Date

09-02-2023
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Horizon Europe
HORIZON.1 Excellent Science
HORIZON.1.1 European Research Council (ERC)
HORIZON.1.1.0 Cross-cutting call topics
ERC-2022-POC1 ERC PROOF OF CONCEPT GRANTS1
HORIZON.1.1.1 Frontier science
ERC-2022-POC1 ERC PROOF OF CONCEPT GRANTS1