Summary
The objectives of this project are to structure ophthalmic polymers by using the Direct Laser Interference Patterning (DLIP)
technique, to study the refractive index modification, and to assess the optical and the microstructural properties of laser
structured samples. DLIP technique allows processing large macroscopic areas with controlled periodic micro- and submicrometer
patterns, in a single step and in very short times, usually in less than one second. These characteristics result in
a higher efficient manufacturing process when compared to conventional laser structuring techniques which allows the
structuring process to be easily implemented at industrial level.
To determine the maximal refractive index variation produced in each type of polymer laser parameters such as wavelength,
pulsewidth, intensity and incident angle will be modified. Both periodic line and circular gratings will be inscribed. In addition,
correlation between optical absorption enhancement and refractive index modification will be carried out. Finally, laser
structured polymers will be manufactured at prototype scale to assess and validate the industrial viability and suitability of
this processing technique for ophthalmic applications, specifically in the case of intraocular and contact lenses.
The Fellowship will be carried out at the Technische Universität Dresden (Host Organisation) and VOPTICA (secondment
organisation). The project involves both Academic sector and Industry.
This proposal involves the following subjects: Optical engineering, photonics and lasers; materials engineering; medical
engineering, biomedical engineering and technology; and lasers, ultra-short lasers and laser physics.
technique, to study the refractive index modification, and to assess the optical and the microstructural properties of laser
structured samples. DLIP technique allows processing large macroscopic areas with controlled periodic micro- and submicrometer
patterns, in a single step and in very short times, usually in less than one second. These characteristics result in
a higher efficient manufacturing process when compared to conventional laser structuring techniques which allows the
structuring process to be easily implemented at industrial level.
To determine the maximal refractive index variation produced in each type of polymer laser parameters such as wavelength,
pulsewidth, intensity and incident angle will be modified. Both periodic line and circular gratings will be inscribed. In addition,
correlation between optical absorption enhancement and refractive index modification will be carried out. Finally, laser
structured polymers will be manufactured at prototype scale to assess and validate the industrial viability and suitability of
this processing technique for ophthalmic applications, specifically in the case of intraocular and contact lenses.
The Fellowship will be carried out at the Technische Universität Dresden (Host Organisation) and VOPTICA (secondment
organisation). The project involves both Academic sector and Industry.
This proposal involves the following subjects: Optical engineering, photonics and lasers; materials engineering; medical
engineering, biomedical engineering and technology; and lasers, ultra-short lasers and laser physics.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/795630 |
| Start date: | 01-04-2019 |
| End date: | 31-03-2021 |
| Total budget - Public funding: | 171 460,80 Euro - 171 460,00 Euro |
Cordis data
Original description
The objectives of this project are to structure ophthalmic polymers by using the Direct Laser Interference Patterning (DLIP)technique, to study the refractive index modification, and to assess the optical and the microstructural properties of laser
structured samples. DLIP technique allows processing large macroscopic areas with controlled periodic micro- and submicrometer
patterns, in a single step and in very short times, usually in less than one second. These characteristics result in
a higher efficient manufacturing process when compared to conventional laser structuring techniques which allows the
structuring process to be easily implemented at industrial level.
To determine the maximal refractive index variation produced in each type of polymer laser parameters such as wavelength,
pulsewidth, intensity and incident angle will be modified. Both periodic line and circular gratings will be inscribed. In addition,
correlation between optical absorption enhancement and refractive index modification will be carried out. Finally, laser
structured polymers will be manufactured at prototype scale to assess and validate the industrial viability and suitability of
this processing technique for ophthalmic applications, specifically in the case of intraocular and contact lenses.
The Fellowship will be carried out at the Technische Universität Dresden (Host Organisation) and VOPTICA (secondment
organisation). The project involves both Academic sector and Industry.
This proposal involves the following subjects: Optical engineering, photonics and lasers; materials engineering; medical
engineering, biomedical engineering and technology; and lasers, ultra-short lasers and laser physics.
Status
TERMINATEDCall topic
MSCA-IF-2017Update Date
28-04-2024
Geographical location(s)
