Preparation of Ag-Fe2O3-Based black and electrically insulating coatings by magnetron sputtering from metal targets

Black and electrically insulating coatings provide touch panel displays with a classic appearance. In this study, black and electrically insulating Ag-Fe2O3-based coatings were prepared using reactive magnetron sputtering, stainless steel and silver foil. The thin films prepared with oxygen introduction and no Ag foil showed blue light absorption and high electrical resistance, which are comparable to those of Fe2O3 single crystals. The optimal Ag foil size for maintaining a high electrical resistivity of 108 omega.sq-1 was determined to be 54 mol%Ag in the film samples. Black and electrically insulating thin films composed of metallic Ag, amorphous Ag-Fe-O, and slightly crystallized Fe2O3 were prepared using 3.4 or 3.9 %O2. Metallic Ag segregated randomly in the high-refractive-index Fe2O3-based matrix, resulting in plasmonic absorption over a wide range of wavelengths centered in the red-wavelength region. At 3.9 %O2, a high sheet resistance of 108 omega.sq-1 and strong visible absorption of 35.2 mu m- 1 (on average), slightly deviating by 2.4 mu m- 1 were simultaneously achieved by clear phase separation of the Ag grains and Fe2O3-based matrix. A clear phase separation mechanism based on thermodynamic nonequilib-rium oxidation of the metallic Ag phase is proposed.

Automated summary

In this study, black and electrically insulating Ag-Fe2O3-based coatings were prepared using reactive magnetron sputtering, stainless steel, and silver foil. The thin films showed blue light absorption and high electrical resistance comparable to Fe2O3 single crystals. By controlling the percentage of Ag in the film samples and the oxygen introduction, black and electrically insulating thin films composed of metallic Ag, amorphous Ag-Fe-O, and slightly crystallized Fe2O3 were obtained. The phase separation mechanism based on thermodynamic nonequilibrium oxidation of the metallic Ag phase was proposed.