Add to ORKGprésentée par L. PinardThe goal of the VIRGO program is to build a giant Michelson type interferometer (3 kilometer long arms) to detect gravitational waves. Large optical components (350 mm in diameter), having extremely low loss at 1064 nm, are needed. Today, the Ion beam Sputtering is the only deposition technique able to produce optical components with such performances. Consequently, a large ion beam sputtering deposition system was built to coat large optics up to 700 mm in diameter. The performances of this coater are described in term of layer uniformity on large scale and optical losses (absorption and scattering characterization). The VIRGO interferometer needs six main mirrors. The first set was ready in June 2002 and its install...
Within the framework of the Virgo project, characterisations of low-absorption high reflectivity mul...
Long baseline optical interferometry is a promising technique for the detection of gravitational wav...
Long baseline optical interferometry is a promising technique for the detection of gravitational wav...
Large optical components (diameter 350 mm), having extremely low loss at 1064 nm, are needed for the...
Large optical components (diameter 350 mm), having extremely low loss at 1064 nm, are needed for the...
présentée par L. PinardThe goal of the VIRGO program is to build a giant Michelson type interferomet...
Large mirrors (∅350 mm) having extremely low optical loss (absorption, scattering, wavefront) were c...
présenté par A. RemillieuxLarge mirrors (350 mm), having extremely low optical loss (absorption, sca...
The second generation of gravitational wave detectors will aim at improving by an order of magnitude...
The Advanced Virgo gravitational wave detector aims at a sensitivity ten times better than the initi...
The new generation of advanced interferometer needs fused silica mirrors having better optical and m...
International audienceFor the first time, direct detection of gravitational waves occurred in the La...
We report on the optical, mechanical and structural characterization of the sputtered coating materi...
Within the framework of the Virgo project, characterisations of low-absorption high reflectivity mul...
Long baseline optical interferometry is a promising technique for the detection of gravitational wav...
Long baseline optical interferometry is a promising technique for the detection of gravitational wav...
Large optical components (diameter 350 mm), having extremely low loss at 1064 nm, are needed for the...
Large optical components (diameter 350 mm), having extremely low loss at 1064 nm, are needed for the...
présentée par L. PinardThe goal of the VIRGO program is to build a giant Michelson type interferomet...
Large mirrors (∅350 mm) having extremely low optical loss (absorption, scattering, wavefront) were c...
présenté par A. RemillieuxLarge mirrors (350 mm), having extremely low optical loss (absorption, sca...
The second generation of gravitational wave detectors will aim at improving by an order of magnitude...
The Advanced Virgo gravitational wave detector aims at a sensitivity ten times better than the initi...
The new generation of advanced interferometer needs fused silica mirrors having better optical and m...
International audienceFor the first time, direct detection of gravitational waves occurred in the La...
We report on the optical, mechanical and structural characterization of the sputtered coating materi...
Within the framework of the Virgo project, characterisations of low-absorption high reflectivity mul...
Long baseline optical interferometry is a promising technique for the detection of gravitational wav...
Long baseline optical interferometry is a promising technique for the detection of gravitational wav...