Skip to main navigation
Skip to search
Skip to main content
Beijing Institute of Technology Home
English
中文
Home
Profiles
Research units
Research output
Prizes
Search by expertise, name or affiliation
View Scopus Profile
Li Jiao
School of Mechanical Engineering
h-index
1635
Citations
22
h-index
Calculated based on number of publications stored in Pure and citations from Scopus
2001
2024
Research activity per year
Overview
Fingerprint
Network
Research output
(131)
Similar Profiles
(11)
Fingerprint
Dive into the research topics where Li Jiao is active. These topic labels come from the works of this person. Together they form a unique fingerprint.
Sort by
Weight
Alphabetically
Engineering
Cutting Force
100%
Grinding (Machining)
96%
Surface Quality
87%
End Milling
68%
Fractal Dimension
59%
High Strength Steel
51%
Ultrasonics
51%
Monocrystal
51%
Machined Surface
44%
Surface Integrity
42%
Cutting Fluid
42%
Milling Micro
39%
Finite Element Method
36%
Feed Rate
34%
Finite Element Modeling
34%
Machining Quality
34%
Cutting Parameter
33%
Rake Angle
33%
Experimental Result
31%
Cutting Performance
28%
Cutting Speed
27%
Ground Surface
27%
Thrust Force
27%
Grinding Machine
25%
Ti-6al-4v
25%
Mesoscale
25%
Robot
25%
Residual Stress
24%
Illustrates
23%
Obtains
22%
Mathematical Model
22%
Simulation Result
21%
Surface Topography
21%
Austenitic Stainless Steel
21%
Material Removal
20%
Strain Rate
20%
Experimental Investigation
20%
Roundness
20%
Process Parameter
19%
Microstructure
18%
Inclination Angle
18%
Fatigue Life
18%
High Strain Rate
18%
Milling Cutters
18%
Cantilever Beam
17%
Great Influence
17%
Deep Hole
17%
Intrinsic Mode Function
17%
Gas Fuel Manufacture
17%
Rate of Convergence
17%
Material Science
Machining
92%
Surface Roughness
76%
Surface Texture
46%
Fretting
41%
Cutting Fluid
40%
Fatigue of Materials
34%
Conformal Contact
34%
Diamond
32%
Surface Topography
30%
Residual Stress
29%
Fretting Fatigue
29%
Surface Property
28%
Superalloys
27%
Sapphire
25%
Nickel-Based Superalloys
25%
Corrosion
25%
Strain Rate
25%
High Entropy Alloys
25%
Crack Initiation
23%
Finite Element Method
19%
Magnesium Alloy
18%
Carbon Dioxide
17%
Optical Glass
17%
Shaft
17%
High Strength Steels
17%
Fretting Wear
14%
Nucleation
13%
Ceramic Material
12%
Finite Element Modeling
12%
Titanium Alloys
12%
Ti-6Al-4V
11%
Hydrodynamics
11%
Lubrication
10%
Silicon Dioxide
10%
Brittleness
10%
Polishing
10%
Microstructure
10%
Contact Area
10%
Crack Propagation
10%
Fatigue Crack
10%
Yield Stress
10%
Aluminum Alloys
10%
Density
9%
Biaxial Fatigue
8%
Sliding Wear
8%
Surface Finishing
8%
Non-Conformal Contact
8%
Low Temperature Lubricant
8%
Fatigue Behavior
8%
Stress Concentration Factor
8%
