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Di Wan
Advanced Research Institute of Multidisciplinary Science
h-index
1490
Citations
22
h-index
Calculated based on number of publications stored in Pure and citations from Scopus
2011
2024
Research activity per year
Overview
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Research output
(67)
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(2)
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Dive into the research topics where Di Wan is active. These topic labels come from the works of this person. Together they form a unique fingerprint.
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Weight
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Material Science
Alloying
14%
Aluminum
9%
Aluminum Alloys
9%
Austenitic Stainless Steels
9%
Brittle Fracture
9%
Crack Growth
17%
Crack Initiation
11%
Crack Tip
8%
Creep
13%
Density
23%
Desorption
22%
Dual Phase Steel
7%
Elastic Moduli
11%
Electron Backscatter Diffraction
21%
Embrittlement
7%
Fatigue Behavior
15%
Fatigue Crack
8%
Fatigue Crack Growth
45%
Fatigue of Materials
10%
Ferritic Steel
14%
Fractography
12%
Grain Boundary
30%
Heat Treatment
22%
High Entropy Alloys
100%
High Strength Steels
14%
Hydrogen Embrittlement
46%
Hydrogen Storage Alloys
7%
Indentation
8%
Laser Powder Bed Fusion
12%
Manganese
10%
Martensite
8%
Matrix Composite
9%
Mechanical Strength
44%
Nanohardness
9%
Nanoindentation
54%
Nanoparticle
8%
Nucleation
16%
Powder
7%
Scanning Electron Microscopy
57%
Silicon Alloys
14%
Solidification
22%
Strain Rate
15%
Tensile Loads
9%
Tensile Testing
13%
Thermal Stability
7%
Thermomechanical Processing
10%
Three Dimensional Printing
68%
TWIP Steel
14%
Work Hardening
9%
Yield Stress
19%
Engineering
Additive Manufacturing
34%
Alloy Element
7%
Alloy System
7%
Austenitic Stainless Steel
9%
Bainite
7%
Butt Welding
7%
Channelling
7%
Crack Growth Rate
19%
Defects
12%
Deformation Behavior
10%
Deformation Mechanism
9%
Dislocation Density
7%
Dual Phase Steel
7%
Effective Stress
7%
Energy Engineering
10%
Environmental Scanning Electron Microscope
16%
Fatigue Behavior
14%
Fatigue Crack Growth
28%
Fatigue Performance
7%
Fault Plane
11%
Ferritic Stainless Steel
7%
Grain Boundary
10%
High-Entropy Alloys
28%
Hydrogen Embrittlement
20%
Hydrogen Storage
14%
Imaging Contrast
7%
Internal Stress
10%
Joints (Structural Components)
7%
Laser Engineered Net Shaping
7%
Length Scale
7%
Martensite
14%
Material Extrusion
11%
Mechanical Testing
9%
Microstructure
25%
Mockups
7%
Nanoindentation Test
7%
Polyurethan
7%
Powder Bed Fusion
7%
Ray Diffraction
7%
Scanning Electron Microscope
8%
Single Edge
7%
Steel Pipeline
14%
Strength Mismatch
9%
Stress Field
14%
Stress Level
10%
Subgrains
7%
Tensile Loads
10%
Tensile Test
13%
Transmissions
9%
TWIP Steel
7%
