University of Technology of Troyes

 

 

Content

  1. A. Gokarna, R. Parize, H. Kadiri, K. Nomenyo, G. Patriarche, P. Miska, and G. Lerondel. Highly crystalline urchin-like structures made of ultra-thin zinc oxide nanowires. RSC Adv., 4:47234–47239, 2014.
  2. Roy Aad, Christophe Couteau, Sylvain Blaize, E. Chastaing, F. Soyer, Laurent Divay, C. Galindo, Pierre Le Barny, V. Sallet, C. Sartel, Efficient pump photon recycling via Gain assisted Waveguiding Energy Transfer (G-WET). ACS Photonics 1(3), 246–253, 2014.
  3. R. Tellez-Limon, M. Fevrier, A. Apuzzo, R. Salas-Montiel, and S. Blaize. Theoretical analysis of bloch mode propagation in an integrated chain of gold nanowires. Photon. Res., 2(1):24–30, 2014.

secondary content

GDR ondes Workshop

From June 1, 2016 to June 2, 2016

Les Journées Plasmonique Non-linéaire & Quantique auront lieu le 1 et 2 juin 2016 sur le Campus Saint-Charles à Marseille.

Program: Program GDR ondes 2016

The 14th International Conference on Near-Field Optics, Nanophotonics, and Related Techniques (NFO-14).

NFO-14

From October 18, 2015 to October 20, 2015

NFO-14

 IMPORTANT DATES & DEADLINES

Early registration:
June 30, 2016

NFO-14 conference:
September 4-8, 2016
-9/4 NFO School, Reception
-9/5 Keynote talks
-9/8 Excursion, Banquet

 

Link: http://nfo-14.org

Closing Ceremony of the International Year of Light and Light based Technologies 2015.

Feb. 4-6, 2016, Merida, Yucatan, Mexico

From February 4, 2016 to February 6, 2016

IYL 2015

Closing ceremony

http://www.iyl2015closing.org

RENATECH's thesis prizes 2015 for Komla NOMENKO

Komla NOMENYO will bee awarded by the French National nanofabrication network (RENATECH) in october 2015 for his work on “ ZnO based UV photonics : Enhanced emission and energy transfer through top-down micro and nanostructuring ” 
At the LNIO, Institut Charles Delaunay (CNRS UMR 6281, UT Troyes).

 

Congratulations Komla!

 

Link: RENATECH news

Actualités scientifiques de l'INSIS

From April 15, 2015 to April 15, 2015

Nanofocusing nanodevice

Des chercheurs ont obtenu la super-focalisation d’un champ lumineux dans un nano-dispositif, en intégrant une structure plasmonique, jouant le rôle de concentrateur de lumière, sur un guide d’ondes en silicium. Le confinement extrême de la lumière a pu être observé par une technique de microscopie à champ proche, développée au LNIO.

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