跳至主導覽
跳至搜尋
跳過主要內容
國立陽明交通大學研發優勢分析平台 首頁
English
中文
首頁
人員
單位
研究成果
計畫
獎項
活動
貴重儀器
影響
按專業知識、姓名或所屬機構搜尋
查看斯高帕斯 (Scopus) 概要
黃 爾文
教授
材料科學與工程學系
智慧半導體奈米系統技術研究中心
https://orcid.org/0000-0003-4986-0661
電話
03-5712121#55307
電子郵件
ewenhuang
nycu.edu
tw
網站
http://ewen-lab.wixsite.com/ewenlab
h-index
h10-index
h5-index
2645
引文
28
h-指數
按照存儲在普爾(Pure)的出版物數量及斯高帕斯(Scopus)引文計算。
1647
引文
22
h-指數
按照存儲在普爾(Pure)的出版物數量及斯高帕斯(Scopus)引文計算。
1078
引文
16
h-指數
按照存儲在普爾(Pure)的出版物數量及斯高帕斯(Scopus)引文計算。
2003
2024
每年研究成果
概覽
指紋
網路
計畫
(11)
研究成果
(134)
獎項
(9)
活動
(6)
類似的個人檔案
(6)
指紋
查看啟用 E-Wen Huang 的研究主題。這些主題標籤來自此人的作品。共同形成了獨特的指紋。
排序方式
重量
按字母排序
Keyphrases
High-entropy Alloy
76%
Additive Manufacturing
53%
CoCrNi Medium-entropy Alloy
47%
In Situ Neutron Diffraction
34%
Room Temperature
27%
Crack Tip
27%
Synchrotron X-ray
26%
Mechanical Properties
25%
Lattice Strain
23%
Neutron Diffraction
22%
Microstructure
21%
In Situ
20%
Deformation Mechanism
19%
Neutron Diffraction Method
18%
Cyclic Loading
18%
CoCrFeMnNi
17%
Plastic Deformation
17%
Dislocation
17%
Fatigue Crack Tip
17%
Nickel-based Superalloy
17%
Phase Transformation
16%
Face-centered Cubic
16%
Non-equiatomic
16%
Magnetoresistance
16%
Transmission Electron Microscopy
16%
Yield Strength
16%
Nanoprecipitates
14%
Bulk Metallic Glass Matrix Composites (BMGMCs)
14%
Peak Width
13%
Diffraction Peak
13%
Stainless Steel
13%
Mechanical Behavior
13%
Medium-entropy Alloy
12%
Diffraction
12%
Microstructural Evolution
12%
Ni80Fe20
12%
CoCrFeNi
12%
Dendrite
11%
Structural Heterogeneity
11%
Strain Evolution
11%
Plastic Anisotropy
11%
Compact Tension Specimen
10%
Ni-based Superalloy
10%
Graphite
10%
Crack Growth
10%
Residual Stress
10%
Synchrotron X-ray Diffraction
10%
Small-angle Neutron Scattering
10%
Nickel-based Alloy
9%
Structural Transformation
9%
Material Science
High Entropy Alloys
100%
Neutron Diffraction
71%
Diffraction Measurement
33%
Nickel-Based Superalloys
30%
Plastic Deformation
27%
Three Dimensional Printing
27%
Density
25%
Bulk Metallic Glass
24%
Deformation Mechanism
22%
Stainless Steel
21%
Crack Tip
20%
Work Hardening
20%
Transmission Electron Microscopy
19%
Magnetoresistance
19%
Medium-Entropy Alloy
19%
Piezoelectricity
18%
Austenite
18%
Composite Material
17%
Nickel Alloy
16%
Yield Stress
16%
Mechanical Property
16%
Grain Size
15%
Residual Stress
15%
Synchrotron X-Ray Diffraction
15%
Ultimate Tensile Strength
15%
Low-Cycle Fatigue
15%
Matrix Composite
14%
Heat Treatment
14%
Austenitic Stainless Steel
13%
Corrosion
13%
Anisotropy
12%
Fatigue Crack
12%
Fatigue of Materials
12%
Phase Composition
12%
Microstructural Evolution
11%
Plastic Anisotropy
11%
Surface (Surface Science)
10%
Pure Zinc
10%
Nanofiber
10%
Crystal Structure
10%
Martensite
9%
Crack Growth
9%
Grain Boundary
9%
Selective Laser Melting
9%
X-Ray Diffraction
9%
Nano-Precipitates
8%
Shape Memory Effect
8%
Fatigue Crack Growth
8%
Domain Wall
8%
Permalloy
8%
Engineering
High-Entropy Alloys
28%
Crack Tip
27%
Room Temperature
22%
Additive Manufacturing
19%
Stainless Steel
18%
Tensiles
18%
Fatigue Crack
17%
Piezoelectric
15%
Ray Diffraction
15%
Cyclic Loading
14%
Induced Deformation
14%
Plastic Deformation
12%
Low Cycle Fatigue
12%
Strain Hardening
12%
Fatigue Crack Growth
12%
Deformation Mechanism
12%
Face-Centered Cubic
12%
Hardening Behavior
12%
Dislocation Density
11%
Residual Stress
10%
Core-Shell
10%
Bulk Metallic Glass
10%
Glass Matrix
10%
Anisotropic
10%
Nano-Precipitates
10%
Multiscale
9%
Fatigue Resistance
8%
Electrospun
8%
Porosity
7%
Nanofiber
7%
Fatigue Behavior
7%
Compressive Residual Stress
7%
Isothermal
7%
High Temperature Gas Reactors
7%
Soft Material
7%
Slip System
7%
Experimental Result
7%
Ti-6al-4v
7%
Deposited Energy
7%
Transients
7%
Fatigue Cycle
7%
Retained Austenite
6%
Microstructural Evolution
6%
Crack Growth
6%
Strain Field
6%
Deformation Mode
6%
Crack Growth Rate
6%
Retardation
6%
Nanoparticle
6%
Microscale
6%