-
GRADUATE STUDIES
- • STUDYING AT MANUTECH SLEIGHT
-
MSc in Optics, Image, Vision, Multimedia (OIVM)
-
iPSRS - Intelligent Photonics for Security, Reliability, Sustainability and Safety
- PSRS - Partner universities
- RADMEP - Radiation and its Effects on MicroElectronics and Photonics Technologies
- COSI - Computational Colour and Spectral Imaging
- IMLEX - Imaging & Light in Extended Reality
- AIMA - Advanced Imaging & Material Appearance
- PE - Photonics Engineering
-
iPSRS - Intelligent Photonics for Security, Reliability, Sustainability and Safety
- MSc in Computer Science
- MSc in Health Engineering
- Engineering schools' research tracks
- Doctoral studies
- Training through research
- Opportunities
- Admission and aid
- OPTICA student chapter
-
RESEARCH & INNOVATION
-
SCIENTIFIC EVENTS
- • News and about
-
The SLEIGHT Science Events
- SSE #13 - SLEIGHT in 2025
- SSE #12 - Imaging in Manutech-SLEIGHT
- SSE #11 - SLEIGHT in 2024
- SSE #10 - Sustainable Surface Engineering
- SSE #09 - SLEIGHT in 2023
- SSE #08 - Photonics for Health
- SSE #07 - SLEIGHT in 2022
- SSE #06 - Machine Learning
- SSE #05 - SLEIGHT in 2021
- SSE #03 - SLEIGHT in 2020
- SSE #02 - Material Appearance
- SSE #01 - Topics and stakeholders
- Manutech-SLEIGHT Awards
- Scientific conferences
- Events in partnership with Manutech-SLEIGHT
- CAMPUS LIFE
- ABOUT US
- NEWSLETTER
You are here : EUR MANUTECH SLEIGHT
-
Partager cette page
SCIENTIFIC AXIS 3: Foster a decisive technological leap in engineering and control of light-induced surface modification effects
The third scientific axis aims at improving, assessing or developing surfaces with new functions, and link the effects of surfaces properties with flow properties. The research teams will both exploit the fabrication and the properties (optical, chemical, mechanical, physical...) of micro and nanostructured surfaces, in order to develop functionalised surfaces according to the targeted applications..
- Controlling temporal and spatial ultrashort laser pulse in order to create and master new techniques for direct surface functionalisation;
- Linking the effects of the surface roughness properties, channel geometry, Reynolds number and surface structure obtained from light engineering with flow properties to go on long-term towards the development of a non-Newtonian viscosity model, to be applied to rheologically complex bio-liquids;
- Developing micro and nano-structured and functional surfaces with optical, mechanical, chemical and physical properties, and extending functionalities to 3D designs for sensing and imaging;
- Assessing the material’s surface in terms of structural and microstructural features and multifunctional properties.
RESEARCH PROJECTS
-
Optical sensor based on hydrogenated amorphous silicon (a-Si: H)
-
Advanced Laser Patterning for Engineering of Standardized Bio-chips
-
FAutes sur Microcontrôleur avec un banc lASer multi-spots
-
Functionalization of metal surfaces by micro-nanostructuring sol-gel
-
Thin passive films characterization by surface plasmon resonance
-
Eye Anterior segment Laser Engineering
-
Additive manufacturing by stereolithography of tough ceramics for medical application
-
Femtoseconde LASer for dental IMPlants multifonctionnal texturing
-
SPR-based sensors for monitoring in vitro bone models
-
Periodic Van Der Waals Origamis by Ultrafast Laser Nanotexturing
-
Magnetic field steering Of the Thermo-chromic behavior Of Micro-structured surfaces
-
TRAPping of extracellular vesicle by femtosecond laser-generated NANOstructures: a new approach to surface biofunctionalization
-
SPR-based biosensors for in vitro bone models
-
VErsatile ZnO-based Plasmonics semiconducting substrates for biomedical Applications
-
Prediction of laser-printed multidimensional colours on plasmonic metamaterials using deep learning and adaptative strategies