Engineering & Materials Science
Composite materials
100%
Fatigue of materials
77%
Crack initiation
69%
X rays
68%
Surface roughness
62%
Plastic deformation
61%
Residual stresses
59%
Amorphous alloys
57%
Reinforcement
55%
Particle reinforced composites
52%
Microstructure
49%
Compression testing
48%
Hydrogels
44%
Surface defects
41%
Characterization (materials science)
40%
Volume fraction
35%
Fatigue crack propagation
35%
Plastic flow
35%
Crack propagation
34%
Extrusion
32%
Austenitic stainless steel
32%
Spatial distribution
31%
Sensitivity analysis
30%
Ductile fracture
28%
Numerical models
28%
Metallic glass
24%
Defects
23%
Tomography
23%
Tissue
19%
Cracks
17%
Light metals
17%
High strength steel
15%
3D printers
13%
Tensile testing
13%
Calibration
13%
Debonding
12%
Finite element method
11%
Magnesium
11%
Metals
11%
Surface topography
10%
Chemical analysis
9%
Mechanical properties
9%
Stress relaxation
8%
Tissue engineering
7%
Encapsulation
6%
Cells
5%
Relaxation
5%
Nucleation
5%
Steel
5%
Chemical Compounds
Composite Material
85%
Plastic Deformation
85%
Residual Stress
82%
Surface Roughness
73%
Microstructure
71%
Molecular Cluster
66%
Crack Initiation
63%
Crack Propagation
60%
Amorphous Material
59%
X-Ray
48%
Surface Defect
40%
Extrusion
34%
Alloy
30%
Surface
29%
Hydrogel
27%
Volume
23%
Simulation
22%
Magnesium Atom
21%
Flow
21%
Gellan Gum
17%
Shape
16%
Heterogeneity
16%
Fatigue Limit
15%
Additive
15%
Fatigue Strength
11%
Amount
10%
Stress-Strain Relationship
9%
Stress Relaxation
9%
Metallic Glass
9%
Metal
8%
Nucleation
7%
Polymer Network
6%
Resistance
5%
Physics & Astronomy
particulate reinforced composites
57%
metal matrix composites
41%
composite materials
18%
reinforcement
18%
mechanical properties
9%
microstructure
8%
crack initiation
7%
plastic flow
7%
damage
7%
matrices
5%
elastoplasticity
5%
cracks
5%