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Organisation/Company CNRS Department Institut de physique de Nice Research Field Engineering Physics Technology Researcher Profile First Stage Researcher (R1) Country France Application Deadline 10 Jul 2025 - 23:59 (UTC) Type of Contract Temporary Job Status Full-time Hours Per Week 35 Offer Starting Date 1 Oct 2025 Is the job funded through the EU Research Framework Programme? Horizon Europe - MSCA Is the Job related to staff position within a Research Infrastructure? No

Over the past four decades, glass, glass-ceramics and composites have contributed to the most advanced socio-economic breakthroughs as high-tech materials. To compete with emerging economies such as China and India, the European glass sector must strive for product leadership by investing more in research and innovation to develop new materials and train specialists for a competitive but promising market.
Contributing to this challenge is the main objective of the 'Structured functional glasses for lasing, sensing and health applications' (FunctiGlass) project, dedicated to advanced high-tech materials for three sectors: light sources, sensors and biological applications.
FunctiGlass, coordinated by CNRS, is a unique interdisciplinary research and training programme with a double degree as part of Horizon Europe's Doctoral Networks (Marie-Sklodowska Curie Actions, project 101169415). It will train 11 doctoral candidates who will take part in a joint research training programme based on very close cooperation between academia and industry. It will ensure that the trainees are exposed to 11 academic environments (universities and research institutes) and 9 non-academic environments (industry and SMEs) representing 9 different countries. Each PhD candidate will be supervised by two academic tutors from different countries (spending her/his time between both units) and one mentor (industrial partner) to ensure cross-sector knowledge sharing and the acquisition of transferable skills with a focus on entrepreneurship and innovation. Through the multi-dimensional training of the FunctiGlass programme, the 11 PhD candidates will excel in the future economy by acquiring a multi-dimensional perspective and mindset to become future leaders in glass science and in particular glass-based nano/micro-structured materials. Through this programme, they will find their own path of innovation in academia or industry.
The project will create the conditions necessary for the establishment of long-term relationships between the academic and private sectors for the transfer of technologies and skills.
5 institutions will award the double degrees: Université Côte d'Azur (Nice, France), Tampere Universities (Finland), Gottfried Wilhelm Leibniz University Hannover (Germany), University Milano-Bicocca (Italy) and the Institute of Low Temperature and Structure Research, Polish Academy of Sciences (Wroclaw, Poland).
Industrial partners: AOI Tech (France), Corning (France), Fastlite (France), Klearia (France), Else Nuclear (Italy), Nobula3D (Sweden), Nyfors Teknologi (Sweden), Rosendahl Nextrom (Finland), Scout Scientific Outsourcing (Poland).
Other universities involved in the project as partners (not awarding doctoral degrees): University of Cergy-Pontoise (France), University of Gent (Belgium), University of Pardubice (Czech Republic), University of Nazarbayev (Kazakhstan), Umeå University (Sweden).

For this thesis, lasting 4 years, the host laboratory is Institut de Physique de Nice (Nice, France) and the supervisor is Wilfried Blanc. The co-host laboratory is Photonics Laboratory, Tampere University (Finland), with Laeticia Petit as co-supervisor. The industrial mentor is NYFORS (Sweden). The candidate will share her/his time between both countries.

Since the advent of optical fibers in the 1980s, silica glass has proven to be the most widely used thanks to its many qualities. The development of manufacturing processes has made it possible to make this glass extremely transparent, with light being able to propagate over 100 km before losing 99% of its initial intensity. This ultra-transparency has led to the era of optical communications. Its rise has also been accompanied by the development of an amplifying fiber doped with rare earth ions (erbium ions, Er3+) to amplify light for wavelengths around 1.5 µm [1]. Again, this fiber was made from silica. Despite all these successes, silica fibers also have limitations imposed by glass. For example, the luminescence properties are linked to the chemical and structural environment of the rare earth ions. A crystalline environment could thus be interesting for producing fiber lasers because the absorption and emission cross sections are higher than in glass.

To meet this expectation, a new family of optical fibers is being developed. Its originality lies in the presence of nanoparticles within the core of the optical fiber [2]. This approach makes it possible to keep a silica glass while providing new properties thanks to the presence of nanoparticles. By embedding rare earth ions in these nanoparticles, the new chemical and structural environment thus opens up new luminescence properties.

Nanoparticles in optical fibers can be obtained mainly by two routes. The first is based on thermodynamic mechanisms to form nanoparticles by phase separation [3]. The second approach consists in pre-synthesizing nanoparticles and including them in the glass. It is this second route that will be more particularly studied during this thesis. Although it appears simpler than the first approach, the difficulty of doping with pre-synthesized nanoparticles lies in their survival throughout the manufacturing process because of the high temperatures involved. The Institute of Physics of Nice (France) and the Photonic Glasses Group at Tampere University (Finland) reported for the first time that doping with YbPO4 crystals led to the presence of these same crystals in the optical fiber [4]. This result constitutes the starting point of this research topic. During the PhD thesis, nanocrystals (doped with Er3+ ions) of different compositions will be prepared by chemical route. They will then be inserted into glasses prepared by the melting process or by the Modified Chemical Vapor Deposition process. The glass rods thus obtained will then be drawn into optical fibers. The nanoparticles will be characterized at each stage to follow their evolution, as well as the luminescence properties of the Er3+ ions.

The main objectives of the PhD are to:
- Advance the fundamental understanding of the synthesis of Er3+ nanoparticles with tailored size, size distribution and spectroscopic properties
- Ensure the survival and dispersion of the nanoparticles in the silica and silicate preforms prepared using MCVD and melting process
- Determine the key parameters during the drawing process to fabricate nanoparticles containing fibers with low loss and strong spectroscopic properties

[1] E. Desurvire, Erbium-Doped Fiber Amplifiers: Principles and Applications, 2002, Wiley
[2] A. Veber, Z. Lu, M. Vermillac, F. Pigeonneau, W. Blanc, and L. Petit, Nano-structured optical fibers made of glass-ceramics, and phase separated and metallic particle-containing glasses. Fibers, 7(12), p.105, 2019
[3] W. Blanc, V. Mauroy, L. Nguyen, B.N. Shivakiran Bhaktha, P. Sebbah, B.P. Pal, and B. Dussardier, Fabrication of rare earth‐doped transparent glass ceramic optical fibers by modified chemical vapor deposition. Journal of the American Ceramic Society, 94(8), pp.2315-2318, 2011
[4] Z. Lu, N. Vakula, M. Ude, M. Cabié, T. Neisius, F. Orange, F. Pigeonneau, L. Petit, and W. Blanc, YbPO4 crystals in as-drawn silica-based optical fibers. Optical Materials, 138, p.113644, 2023