Thin-Film Coating with Reduced Optical Reflection Coefficient Based on Germanium Nanoporous Layer

A method for producing a coating with a reduced optical reflectivity coefficient based on nanoporous Ge layers by implantation of monocrystalline c-Ge with ²⁰⁹Bi⁺⁺ ions at an energy of E = 72 keV, a current density of J = 5 μA/cm² and a dose interval of D = 1.3 ꞏ 10¹⁵—2.5 ꞏ 10¹⁶ ion/cm² is proposed. It is found that starting from D = 6.2 ꞏ 10¹⁵ ion/cm², an swelling spongy Bi:PGe layer with a thickness of about 100 nm is formed. This layer consists of thin intertwined Ge nanowires, which does not change morphological features with the increasing of values D. The layer is characterized by a low optical reflectivity coefficient (< 3%) in the visible spectral range.

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