Description du projet
Mesurer la pollution atmosphérique à l’aide de semi-conducteurs en carbure de silicium
La pollution atmosphérique ne cesse d’avoir des répercussions significatives sur notre santé. Des taux élevés de dioxyde d’azote (NO2) et de particules sont considérés comme les risques environnementaux les plus importants pour la santé publique dans les zones urbaines. C’est pour cela que la surveillance de la qualité de l’air n’a jamais été aussi importante pour promouvoir la sensibilisation et les stratégies sur la qualité de l’air. Le projet SiC-MOSFET, financé par l’UE, prépare la commercialisation internationale de sa technologie de capteurs de gaz. Développée après plus de 20 ans de recherche, elle repose sur l’utilisation du carbure de silicium (SiC) dans des semi-conducteurs. Comparés à d’autres capteurs actuellement commercialisés, les capteurs SenSiC fournissent une fonctionnalité totale à très haute température et dans des environnements hostiles (des systèmes de chauffage domestiques à des moteurs de voiture) et sont exceptionnellement sensibles à des concentrations en gaz très faibles.
Objectif
Air pollution remains one of the biggest environmental risks to public health in Europe and causes an estimated 422 000 premature deaths per year. Nevertheless, many European countries are still failing to meet air quality standards. Poor human health, heart and lung diseases, reduced labour productivity are all unnecessary consequences that result in additional expenditures for health, environment and penalty payments for excess emissions. SenSIC attempts to address these challenges by offering its gas sensors for harsh environments.
SenSiC’s gas sensor technology has been developed over 20 years of research and is based on the use of Silicon Carbide (SiC) for semiconductors. Unlike existing sensors on the market, the SenSiC sensors offer full functionality in very high temperatures (up to 650C) and harsh environments such as domestic heating systems, process industry, automotive and marine engines etc. Because the sensor semiconductor chip is placed directly in the exhaust gases (in situ), there is no extra cooling delay as with other sensors, and therefore the response is quick. A single sensor unit can detect multiple gases as well as pressure.
Our technology has exceptional sensitivity in very low gas concentrations with a proven long term performance. By measuring gas concentrations, e.g. for NH3, NOx, O2 and CO, it is possible to control the combustion and by that reduce harmful emissions. This leads to a cleaner environment and higher quality of the air we all breath.
The key objective of our project is to transform an initial business plan into a robust strategy for international commercialization and to prepare for a Phase 2 development. With this objective in mind, our Phase 1 project will focus on a more precise market evaluation and developing a plan for future demonstration activities, including reference user and application selection. Through the market part of the feasibility assessment, we will further optimize our go-to-market strategy
Champ scientifique
- engineering and technologymechanical engineeringthermodynamic engineering
- social scienceseconomics and businesseconomicsproduction economicsproductivity
- engineering and technologyenvironmental engineeringair pollution engineering
- engineering and technologyelectrical engineering, electronic engineering, information engineeringelectronic engineeringsensors
- natural sciencesphysical scienceselectromagnetism and electronicssemiconductivity
Programme(s)
Régime de financement
SME-1 - SME instrument phase 1Coordinateur
164 40 KISTA
Suède
L’entreprise s’est définie comme une PME (petite et moyenne entreprise) au moment de la signature de la convention de subvention.