The international Master in Light Sciences and Technologies is part of the University of Bordeaux Graduate Research School.
Selected as a French Initiative of Excellence, the program focuses on knowledge and innovation in light sciences and technologies, providing a multidisciplinary environment for first-class research and education.
The Light Sciences and Technologies Graduate program is an integrated, interdisciplinary program, provided by both academic and industrial experts. The Master is embedded in a cross-fertilizing research environment, adapted to future professions within photonic industries.
The generation, transport, manipulation, detection, and use of light are at the heart of the multidisciplinary Science of Photonics. Today, Laser and photonics is not solely a driver for innovation in manufacturing; the photonic technologies, laser tools, and process systems are themselves becoming products.
Scientific scope
- Laser & Photonics
- Extreme regimes of light
- Materials for photonics
- Quantum sciences & Quantum technologies
- Condensed matter
- Nanosciences
- Optoelectronics
- Photochemistry
- Molecular photonics
- Biophotonics & Imaging
Strengths of the program
- Integrated and interdisciplinary education program provided by academic and industrial experts
- Immersive training in research laboratories and the industrial R&D centers
- Extensive hands-on training is given in state of the art research facilities and infrastructures
- Transverse skills modules
- International mobility and/or training in industry
The interdisciplinary graduate program in Light Sciences and Technologies focuses on three domains of excellence of the University of Bordeaux:
Light Generation, Manipulation and Detection
The generation, transport, manipulation, detection and use of light are at the heart of the photonics domain of excellence. The development of laser systems has led to expertise in nonlinear-optical phenomena and exploitation of these effects for nonlinear-optical devices and optimized laser systems. The optical materials design involves state-of-the-art knowledge on the synthesis, structure, characterization tools, properties (including optical properties) and application (including luminescence) of functional materials. Photonics, micro- & nano-optics local expertise addresses various research fields such as: Plasmonics, Photonic nanomaterials/metamaterials/meta-surfaces, Optical nano emitters and nanoantennas. The light and energy domain covers expertise on low-energy light sources, intelligent lighting controls and solar energy conversion (photovoltaics and other solar energy harvesting technologies). Light detection research includes advanced detection systems for sensing and imaging and photo-detection architectures.
Extreme regime of light
The heralding of a new paradigm in the application of high power lasers is enabling a unique range of fundamental and applied sciences, and new technologies, including novel particle accelerators, light initiated nuclear reactions research, laboratory astrophysics, condensed matter under high pressure, novel x-ray sources, and strong-field QED, amongst others. At the same time, the complementary development of Nanosciences and quantum physics has allowed making tremendous progress in the mastering of electronic excitations in nanostructured materials and devices and on the quantum properties of matter at ultra-low temperatures. Strong synergies are now expected from the mustering of both approaches to Extreme Regimes of Light. This specialty will require a good knowledge of mathematics, optics, electrodynamics, experimental physics and basics of quantum mechanics.
Light imaging and biophotonics
Concepts in light imaging are often approached from the angle of methodology which reflects the duality of this broad field of science and engineering: the constant need for development of new investigation methodologies for pushing the limits of current performances, and the clever application of state-of-the-art methods for specific (bio)applications. This duality, however, requires the acquisition of common basic knowledge: a set of multidisciplinary skills in physics, chemistry and biology to understand and master the different aspects of light imaging.