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材料力学
工学研究院
機械工学部門
概要
フィンガープリント
ネットワーク
プロファイル
(7)
研究成果
(891)
フィンガープリント
材料力学が活動している研究トピックを掘り下げます。これらのトピックラベルは、この組織のメンバーの研究成果に基づきます。これらがまとまってユニークなフィンガープリントを構成します。
並べ替え順
重み付け
アルファベット順
Engineering
Crack
100%
Fatigue Limit
85%
Steel
76%
Alloy
64%
Fatigue Crack Growth
61%
Hydrogen Gas
55%
Characteristics
41%
Crack Propagation
41%
Fatigue Crack Propagation
38%
Fatigue Strength
37%
Fracture
37%
Defects
35%
Fatigue Crack
35%
Mechanisms
33%
Austenitic Stainless Steel
31%
Fracture Surface
31%
Surfaces
30%
Mechanical Fatigue Test
29%
Body Force
29%
Crack Growth Rate
28%
Aluminum Alloys
28%
Evaluation
28%
Strain
27%
Stress-Intensity Factor
24%
Microstructure
24%
Hydrogen Embrittlement
21%
Crack Length
21%
Ultimate Tensile Strength
21%
Tensiles
20%
Fatigue Behavior
20%
Crack Growth
20%
Precipitation
20%
Impact Toughness
20%
Tensile Test
19%
Strain Rate
19%
Notched Specimen
19%
Reliability
18%
Cycles
17%
Hardness
17%
Prediction
17%
Applications
16%
Strain Localization
15%
Dislocation
15%
Grain Boundary
15%
Models
15%
Internals
14%
Deformation
14%
Stress Concentration
14%
Gas Environment
14%
Threshold Stress Intensity Factor
14%
Room Temperature
14%
Design
13%
Crack Growth Behavior
13%
Defect Size
13%
Environment
13%
Plastic Strain
12%
Crack Initiation
12%
Infinite Solid
12%
Measurement
12%
Focused Ion Beam
12%
Striation
12%
Small Crack
12%
Reduction
12%
Dynamic Strain Aging
11%
Plain Specimen
11%
Strain Hardening
11%
Crack Initiation Fatigue
11%
Smooth Specimen
11%
Hybrid Composite
10%
Failure (Mechanical)
10%
Propagating Crack
10%
Welds
10%
Stress Field
10%
Plastic Deformation
10%
Long Crack
9%
High Strength Steel
9%
Temperature
9%
Crack Problem
9%
Experimental Result
9%
Stress Amplitude
9%
Infinite Body
9%
High Strength
9%
Testing
9%
Damage Accumulation
9%
Aging
8%
Mechanical Properties
8%
Properties
8%
Development
8%
Fatigue Property
8%
Prestrain
8%
Austenite
8%
Stages
8%
Welding
8%
Density
8%
Stainless Steel
8%
Notch Root
8%
TWIP Steel
8%
Finite Element Modeling
8%
Elements
8%
Pearlite
8%
Material Science
Crack
86%
Spring Steel
82%
Crack Tip
71%
Fatigue Crack Growth
65%
Hydrogen Embrittlement
59%
Strain
49%
Material
47%
Alloy
41%
Mechanical Strength
40%
Fatigue Crack
37%
Microstructure
37%
Grain Boundary
35%
Fatigue of Materials
31%
Surface
30%
Ductility
30%
Crack Propagation
29%
Defect
29%
Fracture Toughness
27%
Austenitic Stainless Steel
26%
Dislocation
23%
Ultimate Tensile Strength
22%
Aluminum Alloys
21%
Crack Growth
21%
Particle
20%
Carbon Steel
19%
Plastics
19%
Strain Rate
18%
Twinning
17%
Martensite
17%
Hardness
17%
Small Crack
17%
Gas
16%
Magnesium Alloys
16%
Air
16%
Fatigue Behavior
16%
Crack Initiation
15%
Electron Backscatter Diffraction
14%
Ferrite
14%
Tissue
13%
Mechanical Property
13%
Desorption
12%
Low Carbon Steel
12%
Ductile Fracture
12%
Growth Rate
12%
Finite Element Methods
12%
Viscoplasticity
12%
TWIP Steel
11%
Tomography
11%
Temperature
11%
Protective Atmosphere
10%
Crack Closure
10%
Fatigue Damage
10%
Morphology
10%
Dynamic Strain Aging
10%
Density
10%
Aluminum
10%
Metal
10%
Aging of Materials
9%
Solution
9%
Cleavage Fracture
9%
Inclusion
9%
Damage Evolution
9%
Stress Concentration
8%
Dual Phase Steel
8%
Fracture Behavior
8%
Martensitic Stainless Steel
8%
Carbon Fiber Reinforced Plastics
8%
Plastic Deformation
8%
Intermetallics
7%
Work Hardening
7%
Austenite
7%
Nickel-Based Superalloys
7%
Yield Stress
7%
Nucleation
7%
Slip Band
7%
Coating
7%
Tensile Property
7%
Stainless Steel
7%
X-Ray Microtomography
7%
Coalescence
7%
Silicon Alloys
7%
Intergranular Fracture
7%
Bending
6%
Rolling Contact Fatigue
6%
Characterization
6%
Crystalline Material
6%
Ferritic Steel
6%
High Strength Steel
5%
Carbon Fiber
5%
Scanning Electron Microscopy
5%
Age Hardening
5%
Fiber
5%
Vickers Hardness
5%
Grain Size
5%
Cell
5%
Stacking Fault
5%
Hardening
5%
Vacancy
5%
Physics
Hydrogen
97%
Cracks
80%
Fatigue Crack
67%
Steel
53%
Alloy
48%
Fatigue Test
35%
Behavior
35%
Crack Propagation
27%
Region
24%
Fatigue Crack Growth
24%
Fracture
24%
Crack Growth
23%
Grain Boundaries
22%
Deformation
21%
Value
20%
Model
20%
Evaluation
19%
Defects
16%
Bending
16%
Stress Intensity Factors
16%
Crack Initiation
15%
Area
15%
Ultimate Tensile Strength
15%
Shears
15%
Fracture Strength
15%
Cracking (Fracture)
13%
Plane
13%
Hydrogen Embrittlement
12%
Strain
12%
Microstructure
12%
Utilization
12%
Dislocation
12%
Differences
12%
Boundaries
12%
Cycles
12%
Temperature
11%
Voids
11%
Simulation
10%
Martensite
10%
Rotation
10%
Metal
10%
Growth
10%
Air
10%
Strength of Materials
10%
Iron
10%
Tomography
10%
X Ray
10%
Plastic Deformation
10%
Validity
9%
Reliability
9%
Brittle Fracture
9%
Hardness
9%
Fatigue Life
9%
Nitrogen
9%
Calculation
9%
Stress Distribution
9%
Sites
8%
Ratios
8%
Pearlite
8%
Intergranular Fracture
8%
Cleavage
8%
Particle
8%
Environment
7%
Tissue
7%
Dislocation Structure
7%
Frequencies
7%
Plastic Properties
6%
Contrast
6%
Coating
6%
Position (Location)
6%
Images
6%
Room Temperature
6%
Failure
6%
X-Ray Diffraction
6%
Carbon Fiber Reinforced Plastics
6%
Gases
6%
Grain Size
6%
Volume
6%
Composite Material
5%
Molecular Dynamics
5%
Inclusions
5%
Hybrid Composite
5%
Fracture Mechanics
5%
Existence
5%
Statics
5%
Regimes
5%
Grain Refinement
5%
Fatigue Behavior
5%
Increasing
5%
Nucleation
5%
Solder
5%
Initiation
5%
Flat Surfaces
5%
Heat
5%