When going to the nanoscale, the laws governing light change dramaticaly. Fundamental laws of topics need to be revisited. This opens new avenues for applications. Research teams of C’Nano IdF are making key contributions to this optics revolution.

Imaging has always been a major application of optics.
Since Abbe and Rayleigh it had been taken for granted that details finer than half a wavelength cannot be resolved. Hence, optical microscopy was limited to micron-size objects. In the last 20 years, different techniques (Scanning Near-field Optical Microscopy, Stimulated Emission Depletion microscopy, Photo Activated Localization Microscopy) have demonstrated that imaging with a resolution on the order of 10 nm is possible using optical wavelengthd.
This gives access to the "nano-wolrd". These discoveries were the beginning of the exploration of the interaction of the light with matter at the nanoscale. This is the subject of nanophotonics.
Controlling the interaction between light and matter at the nanoscale allows modifying completly the processes of absorption and emission of light. It paves the way to the design of efficient light sources such as energy saving Light Emittin Diodes (LEDs) or to the design of single photon sources that can be used for quantum cryptography for example.
Light sources of this kind are nanoojects that behave like artificial atoms. It become possible to produce light states wich have quantum properties with no classical counterpart, a key ingredient for the development of quantum information.
 Solid-state nanoscale light sources fabrication rely on the development of nanochemistry or semiconductor microfabrication. These powerful techniques are also used to design efficient absorbers that can be used for optimized photovoltaic cells or sensors widely used in bionanoscience and medicine. In order to enhance these interactions, light is concentrated at length scales smaller than the wavelenght using new objects called optical antennas, often made with nanometallic structures.
Let us finally mention that by structuring the matter at a length scale smaller than th wavelength allows to design neu materials called metamaterials with optical properties otherwise not available.
Applications include negative index materilas, materilas with magnetic properties at the optical wavelengths, invisibility cloak to name a few.