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Pei Yan
School of Mechanical Engineering
h-index
1279
Citations
20
h-index
Calculated based on number of publications stored in Pure and citations from Scopus
2008
2024
Research activity per year
Overview
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Research output
(97)
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(9)
Fingerprint
Dive into the research topics where Pei Yan is active. These topic labels come from the works of this person. Together they form a unique fingerprint.
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Engineering
Cutting Force
100%
Surface Quality
61%
Cutting Performance
46%
MoS2
38%
Solid Lubricant
37%
Microhole
36%
End Milling
35%
Cutting Fluid
34%
High Strength Steel
29%
Coated Tool
28%
Grinding (Machining)
28%
Machined Surface
27%
Hardened Steel
26%
Cutting Speed
24%
Residual Stress
24%
Dry-Cutting
23%
Experimental Result
23%
Ti-6al-4v
22%
Robot
22%
Surface Integrity
22%
Finite Element Method
21%
Dry Machining
20%
Rake Face
20%
Obtains
19%
Austenitic Stainless Steel
19%
Cutting Temperature
18%
Stainless Steel
18%
Machining Performance
18%
Microhardness
17%
Strain Rate
17%
Thrust Force
17%
Rake Angle
16%
Physical Vapor Deposition
16%
Cutting Parameter
16%
Great Influence
16%
Fatigue Life
16%
High Strain Rate
16%
Friction Coefficient
15%
Feed Rate
15%
Grinding Machine
14%
Mesoscale
14%
Interlayer
13%
Gaussians
12%
Finite Element Modeling
12%
Cutting Depth
11%
Mathematical Model
11%
Flank Wear
11%
Sliding Wear
11%
High-Speed Steel
11%
Helix Angle
11%
Material Science
Machining
83%
Surface Roughness
50%
Cemented Carbide
46%
Surface Texture
40%
Fretting
36%
Residual Stress
35%
Cutting Fluid
34%
Microhardness
32%
Hardened Steel
31%
Wear Resistance
30%
Fatigue of Materials
30%
Conformal Contact
29%
Arc Ion Plating
28%
Fretting Fatigue
25%
Hard Coating
24%
Superalloys
24%
Nickel-Based Superalloys
22%
Corrosion
22%
Strain Rate
22%
High Entropy Alloys
22%
Surface Property
22%
Finite Element Method
21%
Carbide
20%
Physical Vapor Deposition
18%
Composite Coating
17%
Mechanical Strength
15%
Magnesium Alloy
15%
Surface Morphology
15%
Abrasion
15%
Titanium Alloys
15%
Cutting Tool
15%
Carbon Dioxide
15%
Sliding Wear
14%
Thermal Stress
14%
High Speed Steel
14%
Thermal Expansion
14%
Bond Strength (Materials)
14%
High Strength Steels
14%
Finite Element Modeling
14%
Surface Topography
14%
Delamination
13%
Crack Initiation
13%
Fretting Wear
12%
Surface Fatigue
11%
Nucleation
11%
Crystal Orientation
11%
Composite Films
11%
Ti-6Al-4V
10%
Austenitic Stainless Steels
9%
Lubrication
9%
