Investigation of the Resistance of K-208 Glass with Optically Transparent Al-Si-N Nanocomposite Coatings to High-Speed Microparticle Impact

Results of studying the structural-phase state and mechanical properties of Al-Si-N coatings fabricated by pulsed magnetron sputtering on a K-208 glass substrate are presented. By the method of X-ray diffraction analysis it has been found that the Al-Si-N coatings with a thickness of 6 mu m contain nanoscale hexagonal close-packed (HCP) AlN crystallites. Sputtering of the Al-Si-N coatings allows the nanohardness of the surface layer of the K-208 glass samples to be increased up to 30 GPa and a high level of elastic properties (W-e approximate to 70%) to be maintained. For the examined samples, laboratory tests on the impact of high-speed flows of iron microparticles on the Al-Si-N protective coatings fabricated by the method of pulsed magnetron sputtering have been performed. It is established that sputtering of the Al-Si-N protective coatings with a thickness of 6 mu m allows the resistance of the K-208 glass samples to the impact of iron particles accelerated up to 8 km/s to be increased by a factor of 2.8.