Experimental and numerical study for Cu metal coatings at room temperature via powder spray process

• Published in: Surface & coatings technology Vol. 353; pp. 66 - 74
• Main Authors: Lee, Dong-Won, Cho, Myung-Yeon, Kim, Ik-Soo, Kim, Yong-Nam, Lee, Daeseok, Koo, Sang-Mo, Park, Chulhwan, Oh, Jong-Min
• Format: Journal Article
• Language: English
• Published: Lausanne Elsevier B.V 15.11.2018; Elsevier BV
• Subjects: Aerosol deposition; Coating effects; Compressive properties; Compressive strain; Copper; Cu coating; Deposition; Deposition behavior; Electric properties; Electrical properties; High temperature; Kinetic energy; Kinetics; Metal coatings; Metal films; Numerical modeling; Particle size; Powder spray process; Protective coatings; Room temperature; Substrates; Thermal energy; Cu coating; Numerical modeling; Powder spray process; Deposition behavior; Aerosol deposition; Compressive strain
• ISSN: 0257-8972; 1879-3347
• DOI: 10.1016/j.surfcoat.2018.08.075

The effect of Cu particle size on deposition behavior of Cu coating layer was investigated by experimental and numerical studies to understand coating behavior of metal films during aerosol deposition (AD) process. Experimental results showed that Cu film fabricated using 2 μm Cu powder had high deposition rate, low resistivity, and high internal micro-strain. Moreover, Cu films fabricated using 2 μm Cu powder had dense microstructure and Cu oxide phases due to elevated temperature caused by kinetic energy of impacted particles. However, Cu films prepared with 5 μm Cu powder formed filmy deposition layers with poor structural and electrical properties. Numerical results revealed that the generated strain and heat at the impact interface between the particle and the substrate were significantly decreased with increasing particle size. In contrast, the maximum shock pressure of particles was increased with increasing particle size. These results demonstrate that metal Cu particle with size of about 2 μm is suitable for forming good quality coating layers and that their bonding is associated with high compressive strain and thermal energy. •Effect of Cu particle size on aerosol deposited Cu layer was investigated.•Cu film using 2 μm particles showed high deposition rate, low resistivity, and high micro-strain.•Generated strain and heat at interface between film and substrate were decreased with increasing particle size.•Bonding between Cu particles is associated with high strain and thermal energy.