Material Science
Superalloys
100%
Alloy
86%
Temperature
84%
Dislocation
43%
Stacking Fault
38%
Alloying
34%
Material
33%
Creep
27%
Mechanical Property
23%
Aging of Materials
20%
Titanium Alloys
19%
Density
17%
Nickel-Based Superalloys
17%
Single Crystal
17%
Beta Titanium Alloys
17%
Gum Metal
16%
Transmission Electron Microscopy
15%
Heat Treatment
15%
Microstructure
14%
Oxidation Reaction
14%
Stress Corrosion Cracking
13%
Strain
13%
Synchrotron X-Ray Diffraction
13%
Mechanical Strength
13%
Coarsening
12%
Nickel
11%
Twinning
11%
Elastic Moduli
10%
Defect
10%
Work Hardening
9%
Volume Fraction
9%
Phase Field Model
9%
Atom Probe
9%
Tomography
9%
Carbide
9%
Oxide
9%
Neutron Diffraction
9%
Air
8%
Forging
6%
Ti-6Al-4V
6%
Zircaloy
6%
Chromium
6%
Lithium
6%
TWIP Steel
6%
Oxidation Resistance
6%
Sodium
6%
Strain Rate
6%
Elastic Constant
6%
Micromechanics
6%
Hydride
6%
Physics
Heat Resistant Alloys
55%
Precipitate
31%
High Temperature
17%
Titanium Alloys
17%
Steel
16%
Nickel
16%
Plastic Properties
14%
Stacking Fault Energy
14%
Deformation
14%
Alloy
14%
Twinning
13%
Matrix
12%
Transmission Electron Microscopy
12%
Model
12%
Temperature
9%
Atoms
9%
Electron Microscopy
8%
Single Crystals
8%
Probe
8%
Dislocation
8%
Shears
8%
Tomography
7%
Failure
7%
High Resolution
7%
Embrittlement
6%
Dislocation Mechanism
6%
Metal Matrix Composite
6%
High Strength
6%
Grain Size
6%
Molecular Cluster
6%
Stress Corrosion
6%
Voids
6%
Initiation
6%
Strain
5%
Antiphase Boundaries
5%
Engineering
Superalloys
20%
High Temperature
13%
Dislocation
13%
Phase Field
9%
Nickel-Based Superalloys
8%
Surfaces
7%
Die Forging
6%
Simulation
6%
Field Study
6%
Dislocation Content
6%
Face-Centered Cubic
6%
Multiscale Modeling
6%
Deformation Mechanism
6%
Superlattice
6%
Base Superalloy
6%
Alloy
6%