Adhesion of SiO₂ thin films to plasma-treated SUS304 stainless steel substrates

“…Methods that may contribute to the formation of a diffusion or adhesive diffusion transition layer include heating the coating–substrate system using resistive heating, heating with high-frequency currents, arc heating, heating with capacitive current (dielectric heating), induction heating (heating with eddy currents), and laser heating [ 17 , 18 , 19 , 20 , 21 , 22 ]. Taking into account the above considerations, laser heating was used to increase the adhesion of selected coatings containing titanium nitride.…”

Effect of Laser Heating on the Life of Cutting Tools Coated with Single- and Multilayer Coatings Containing a TiN Layer

“…Methods that may contribute to the formation of a diffusion or adhesive diffusion transition layer include heating the coating–substrate system using resistive heating, heating with high-frequency currents, arc heating, heating with capacitive current (dielectric heating), induction heating (heating with eddy currents), and laser heating [ 17 , 18 , 19 , 20 , 21 , 22 ]. Taking into account the above considerations, laser heating was used to increase the adhesion of selected coatings containing titanium nitride.…”

Effect of Laser Heating on the Life of Cutting Tools Coated with Single- and Multilayer Coatings Containing a TiN Layer

Etching and annealing treatment to improve the plasma-deposited SiOx film adhesion force

CuO thin films produced for improving the adhesion between Cu and Al₂O3 foils in a direct bonded copper (DBC) process