Synergy of elastic strain energy and electron wind force on thin film grain growth at room temperature

Engineering & Materials Science

• Film growth 100%
• Grain growth 78%
• Strain energy 67%
• Electrons 63%
• Thin films 59%
• Temperature 25%
• Grain boundaries 14%
• Current density 13%
• Polycrystalline materials 10%
• Palladium 9%
• Joule heating 9%
• Tensile strain 8%
• Molecular dynamics 7%
• Atoms 7%
• Transmission electron microscopy 7%
• Annealing 6%
• Metals 4%
• Computer simulation 3%
• Hot Temperature 3%

Chemical Compounds

• Strain Energy 80%
• Grain Growth 76%
• Force 42%
• Ambient Reaction Temperature 35%
• Electron Particle 34%
• Strain 26%
• Grain Boundary 26%
• Grain Size 23%
• Nanocrystalline Metal 20%
• Current Density 18%
• Metallic Material 16%
• Polycrystalline Solid 11%
• Annealing 9%
• Palladium 9%
• Molecular Dynamics 9%
• Transmission Electron Microscopy 8%
• Simulation 7%
• Liquid Film 6%
• Application 3%

Physics & Astronomy

• room temperature 35%
• thin films 32%
• electrons 26%
• grain size 18%
• grain boundaries 18%
• energy 18%
• current density 18%
• Joule heating 14%
• palladium 13%
• rooms 11%
• stimuli 11%
• routes 10%
• molecular dynamics 9%
• annealing 7%
• temperature 7%
• metals 6%
• atoms 6%
• simulation 4%