Abstract
The problem of protection of the front surface silver mirrors is a very important one for a number of applications. The atomic layer deposition (ALD) technique provides an efficient way to form a coating, protecting the sensitive surface of silver from a corrosive and oxidizing environment. Moreover, the ALD layer provides extremely high conformality (even when deposited over high aspect ratio features) and has high integrity, efficiently blocking foreign species diffusion to the silver-overcoat interface. We tested the efficiency of the protection of silver mirrors against oxygen plasma exposure by the ALD-deposited Al2O3 layers by combining spectroscopic ellipsometry, reflection measurements and pulsed glow-discharge optical emission spectroscopy (GD-OES) profiling. We have found that for optimal protection, the thickness of the ALD deposited layer should exceed at least 15 nm (about 150 ALD cycles at 150°C). We have also demonstrated that the deposition of 15 nm of a protective ALD-deposited Al2O3 layer does not affect the absolute reflectivity of a silver mirror in the spectral range 320 -2500 nm.
Highlights
Silver is an ideal metal for the front surface mirrors for optics in both visible and infrared wavelength ranges
We have demonstrated that the deposition of 15 nm of a protective Atomic layer deposition (ALD)-deposited Al2O3 layer does not affect the absolute reflectivity of a silver mirror in a spectral range 300 -2500 nm
In this article we report on the study of the resistance of RF magnetron sputtered front surface silver mirrors with the ALD-deposited Al2O3 protective layers to the erosion in oxygen plasma, generated in high-density plasma (HDP) MDECR system
Summary
Silver is an ideal metal for the front surface mirrors for optics in both visible and infrared wavelength ranges. In our studies we tested the efficiency of the protection of silver mirrors by ALD-deposited Al2O3 layers against oxygen plasma exposure by correlating the ellipsometric measurements with the absolute reflection measurements and Glow-Discharge Optical Emission Spectroscopy (GDOES) data. We have found that for optimal protection the thickness of ALD deposited layer should exceed at least 15 nm (about 150 ALD cycles at 150 oC), as thinner layers do not provide reliable protection of silver surface against oxygen plasma.
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