Optimised additive-surface material combinations for reduced friction & wear in internal combustion engines

INIS

• surfaces 100%
• friction 100%
• wear 100%
• additives 100%
• internal combustion engines 100%
• emission 60%
• films 60%
• lubricants 60%
• x radiation 40%
• reduction 40%
• steels 40%
• energy 40%
• x-ray photoelectron spectroscopy 40%
• lubrication 40%
• aluminium 40%
• fuels 40%
• scanning electron microscopy 20%
• levels 20%
• environment 20%
• interactions 20%
• performance 20%
• engineering 20%
• efficiency 20%
• carbon dioxide 20%
• engines 20%
• hydrocarbons 20%
• particulates 20%
• data analysis 20%
• silicon alloys 20%
• lubricating oils 20%

Material Science

• Energy Dispersive X Ray Analysis 100%
• Film 100%
• Aluminum 100%
• X-Ray Photoelectron Spectroscopy 100%
• Lubrication 100%
• Scanning Electron Microscopy 50%
• Bearing Steel 50%
• Lubricant Additive 50%
• Ferrous Metal 50%
• Surface Engineering 50%
• Materials Science 50%
• Film Growth 50%
• Fossil Fuel 50%
• Silicon Alloys 50%
• Carbon Dioxide 50%

Engineering

• Internal Combustion Engine 100%
• Material Combination 100%
• Surface Material 100%
• Energy-Dispersive X-Ray Analysis 66%
• Ray Photoelectron Spectroscopy 66%
• Material Technology 66%
• Fuel Efficiency 33%
• Fossil Fuel 33%
• Reduce Emission 33%
• Detrimental Effect 33%
• Environmental Scanning Electron Microscope 33%
• Antiwear 33%
• Practical Aspect 33%
• Particulate Emission 33%
• Engineering 33%
• Lubricant Additive 33%
• Ferrous Metal 33%
• Bearing Steel 33%