Engineering & Materials Science
Plasmas
100%
Austenitic stainless steel
45%
Nitriding
28%
Zirconia
23%
Nitrogen
20%
Surface treatment
19%
Oxygen
17%
Carbon
16%
Microstructure
15%
Femtosecond lasers
15%
Stainless steel
15%
Light absorption
14%
Polyamides
14%
Polymers
14%
Hydrophilicity
14%
Durability
14%
Defects
13%
Carburizing
13%
Hardening
12%
Twinning
12%
Texturing
12%
Wear of materials
12%
Interfacial energy
12%
Corrosion resistance
12%
Biocompatibility
12%
Alloying
11%
Temperature
11%
Corrosion
11%
X ray diffraction
11%
Metal foil
10%
Escherichia coli
10%
Hardness testing
10%
Spectroscopy
10%
Tensile stress
9%
Surface properties
9%
Contact angle
9%
Glass fibers
9%
Plasticity
9%
Oxygen vacancies
8%
Oxidation
8%
Atomic force microscopy
8%
X ray photoelectron spectroscopy
8%
Microscopic examination
8%
Aging of materials
7%
Aluminum
7%
Osteoblasts
7%
Energy gap
7%
Wear resistance
7%
Raman spectroscopy
6%
Phase control
6%
Austenite
6%
High density polyethylenes
5%
Steel
5%
Chemical analysis
5%
Transmission electron microscopy
5%
Chemistry
Plasma
67%
Surface
31%
Microstructure
17%
Carburizing
14%
Corrosion Resistance
14%
Surface Modification
13%
Nitrogen
13%
Wear
11%
Polyamide
11%
Carbon Atom
10%
Alloying
10%
Foil
9%
Hydrophilicity
8%
Interfacial Energy
8%
Alloy
8%
Diffuse Reflectance Spectroscopy
7%
Corrosion
7%
Glass
6%
X-Ray Diffraction
6%
Fiber
6%
Strength
6%
Microhardness
5%
Face-Centered Cubic Crystal System
5%